Transparent display panel and transparent display device including the same

ABSTRACT

A transparent display panel has an auxiliary electrode region including a partition wall whose a width of a top face is larger than that of a bottom face thereof. The auxiliary electrode region is disposed on a line region within a display region. A second electrode of an organic light-emitting element and a VSS voltage connection line is electrically connected to each other via an auxiliary electrode, such that electrical resistance of the second electrode as a transparent electrode is reduced. Further, the auxiliary electrode region is formed on each of a plurality of line regions respectively including VSS voltage connection lines extending across the display region. Thus, a current is fed to each pixel in the display region in a smooth manner, such that luminance distribution across the panel is uniform.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the priority of Korean Patent Application No. 10-2019-0146625 filed on Nov. 15, 2019, in the Korean Intellectual Property Office, the disclosure of which is hereby incorporated by reference in its entirety.

BACKGROUND Technical Field

The present disclosure relates to a transparent display panel to reduce or minimize occurrence of luminance unevenness therein, and a transparent display device including the panel.

Description of the Related Art

A display device that displays various information using an image includes a liquid crystal display device (LCD), and an organic light emitting diode based display device (OLED).

As an image implementation skill is advanced, in recent years, a demand for a transparent display device in which at least a partial region on which information is displayed is transparent to transmits light so that an object or a background behind the display device is visible to a user in front of the device has increased.

The transparent display device transmits light in front and rear directions. Thus, the device may display information in the front and rear directions of the display device, such that front and rear users in front and rear of the display device may see objects or backgrounds opposite thereto respectively.

For example, the transparent display device implemented as an organic light-emitting display device may include a transparent region that transmits incident light as it is and a light-emitting region that emits light.

BRIEF SUMMARY

In a transparent display device, a transparent electrode having a high sheet resistance is used to improve transparency. Further, when a thickness of the transparent electrode is small in order to improve light transmittance, electrical resistance of the transparent electrode is further increased.

When the transparent electrode having a high sheet resistance is used, differences between low-level voltage (VSS) rise values at positions of a display panel become large. Thus, non-uniformity phenomenon of luminance in the display panel occurs. This may lead to deterioration in display quality, especially in a transparent display device having a large-area display panel.

Accordingly, inventors of the present application have invented a transparent display panel capable of reducing or minimizing occurrence of non-uniformity of luminance in the display panel via introduction of an auxiliary electrode region capable of reducing resistance of a transparent electrode, and a transparent display device including the same.

A purpose of the present disclosure is to provide a transparent display panel including an auxiliary electrode region capable of reducing resistance of a transparent electrode, and a transparent display device including the same.

Further, one or more embodiments of the present disclosure is to provide a transparent display panel including a partition wall structure that may increase or maximize an electrode contact area to further reducing resistance of a transparent electrode while contributing to improved transmittance, and a transparent display device including the same.

Furthermore, one or more embodiments of the present disclosure is to provide a transparent display panel in which luminance is distributed in an uniform manner via electrical connection between a line region and a transparent electrode arranged in a display region, and a transparent display device including the same.

Furthermore, the present disclosure provides a transparent display panel that a partition wall acts as a spacer, thereby to remove a process of forming a separate spacer, and a transparent display device including the same.

The technical benefits of the present disclosure are not limited to the above-mentioned benefits. Other benefits and advantages of the present disclosure, as not mentioned above, may be understood from the following descriptions and more clearly understood from the embodiments of the present disclosure. Further, it will be readily appreciated that the advantages of the present disclosure may be realized by features and combinations thereof as disclosed in the claims.

A transparent display panel according to an embodiment of the present disclosure includes a display region and a non-display region, wherein the display region includes: a plurality of light-emitting regions; a plurality of transmissive regions; a plurality of line regions spaced from each other, each line region extending in one direction; and a plurality of auxiliary electrode regions arranged over a corresponding line region.

In this connection, the light-emitting region includes an organic light-emitting element including a first electrode, an organic light-emitting layer, and a second electrode, wherein at least one of the line regions includes a VSS voltage connection line, wherein the auxiliary electrode region is disposed on the line region including the VSS voltage connection line.

Specifically, the auxiliary electrode region includes: an auxiliary electrode electrically connected to the VSS voltage connection line; a partition wall disposed on the auxiliary electrode, wherein a width of a top face of the partition wall is larger than a width of a bottom face thereof; and an electrode contact composed of a portion of the auxiliary electrode and a portion of the second electrode which contact each other and are electrically connected each other, wherein the electrode contact is positioned inwardly than end of the partition wall

The light-emitting region includes a first color light-emitting region, a second color light-emitting region and a third color light-emitting region, wherein each of the second color light-emitting region and the third color light-emitting region is disposed on a corresponding line region, wherein the first color light-emitting region is disposed between the second color light-emitting region and the third color light-emitting region disposed on the different line regions, respectively, wherein the auxiliary electrode region is disposed between the second color light-emitting region and the third color light-emitting region disposed on the same line region.

Further, the second electrode may include IZO as a material having high diffraction properties.

Further, the partition wall may include a first partition wall structure and a second partition wall structure layered on the first partition wall structure. The first partition wall structure contacts the auxiliary electrode, but the second partition wall structure may be spaced apart from the auxiliary electrode.

According to the present disclosure, introducing the auxiliary electrode region including the partition wall whose the width of the top face is larger than that of the bottom face thereof on the line region within the display region may allow electrically connecting the second electrode of the organic light-emitting element and the VSS voltage connection line to each other via the auxiliary electrode, such that electrical resistance of the second electrode as a transparent electrode may be reduced.

Further, according to the present disclosure, the partition wall structure including the first partition wall structure as a portion of the bank layer and the second partition wall structure stacked on the first partition wall structure and spaced apart from the auxiliary electrode may allow increasing an area of the electrode contact. Thus, the electrical resistance of the second electrode as a transparent electrode may be further reduced. The partition wall size may be reduced, thereby improving transmittance.

Further, according to the present disclosure, forming the auxiliary electrode region on each of the plurality of line regions respectively including the VSS voltage connection lines extending across the display region may allow supplying a current to each pixel in the display region in a smooth manner, such that the luminance in the panel may be made more uniform.

Further, according to the present disclosure, the partition wall of the auxiliary electrode region may be used as a spacer. Thus, a process of forming a separate spacer and a separate region for forming the spacer are not required, thereby to obtain high process efficiency and panel space utilization.

Further specific effects of the present disclosure as well as the effects as described above will be described in connection with illustrations of specific details for carrying out the present disclosure.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a block diagram schematically illustrating a system of a transparent display device.

FIG. 2 is a plan view for schematically illustrating connection and arrangement relationships of components constituting a transparent display device.

FIG. 3 is a schematic cross-sectional view of light-emitting and transmissive regions of a pixel in an organic light-emitting display panel.

FIG. 4 is a more detailed cross-sectional view of a light-emitting region of a pixel in an organic light-emitting display panel.

FIG. 5 shows a connection relationship of line connection pads disposed on a first substrate in a transparent display panel according to an embodiment of the present disclosure.

FIG. 6 to FIG. 10 are plan views showing, based on an interlayer stacking structure, a connection relationship between lines of FIG. 5 in the transparent display panel according to an embodiment of the present disclosure.

FIG. 11 is an enlarged plan view of a A-A′ region in FIG. 8.

FIG. 12 is an enlarged plan view of a B-B′ region of FIG. 11.

FIG. 13 is an enlarged plan view of a C-C′ region of FIG. 11.

FIG. 14 is an enlarged plan view of a D-D′ region of FIG. 9.

FIG. 15 is an enlarged plan view of a E-E′ region of FIG. 10.

FIG. 16 is an enlarged cross-sectional view of a F-F′ region in FIG. 10.

FIG. 17 is an enlarged plan view of a G-G′ region of FIG. 10.

FIG. 18 is an enlarged cross-sectional view of a H-H′ region of FIG. 17.

FIG. 19 is an embodiment of a transparent display device used as a head-up-display.

FIG. 20A shows a long-distance diffraction pattern by a single slit.

FIG. 20B is an illustration of a diffraction effect in a single slit.

FIG. 21A to FIG. 21D show results of a double slit test for a particle, a wave, light and an electron, respectively.

FIG. 22 shows an arrangement of typical quadrangle shaped transmissive regions in a transparent display device.

FIG. 23 shows diffraction phenomenon of light generated when light is incident onto a central region of a transparent display device having the transmissive region shape as shown in FIG. 22.

FIG. 24 to FIG. 26 show embodiments of the present disclosure in which a transmissive region in a transparent display device has a curved shape.

FIG. 27 shows diffraction phenomenon of light generated when light is incident onto a central region of a transparent display device having a circular transmissive region shape as shown in FIG. 26.

FIG. 28 and FIG. 29 show embodiments of the present disclosure in which a transmissive region in a transparent display device has a polygonal shape whose all internal angles are obtuse.

FIG. 30 shows a configuration in which transmissive regions and light-emitting regions of a transparent display device according to an embodiment of the present disclosure are arranged.

FIG. 31A to FIG. 31C show haze value measurements based on transmissive region shape.

FIG. 32 shows haze value measurements based on transmissive region shapes and based on different ppi.

FIG. 33 shows a configuration in which transmissive regions and light-emitting regions of a transparent display device according to another embodiment of the present disclosure are arranged.

FIG. 34 and FIG. 35 show cross-sections of a I-I′ region and a J-J′ region in FIG. 30, respectively.

FIG. 36 and FIG. 37 show a dummy pixel pattern region surrounding the outermost portion of a display region.

FIG. 38 specifically shows an arrangement relationship between a line region and a pixel circuit region in a display region according to an embodiment of the present disclosure.

FIG. 39 shows a circuit of a pixel circuit region connected to a line region of a K-K′ region.

FIG. 40 shows a circuit of one pixel circuit region.

FIG. 41 to FIG. 43 show cross-sectional views of L-L′, M-M′, and N-N′ regions in FIG. 38, respectively.

FIG. 44 shows a specific arrangement relationship between a line region and an auxiliary electrode region in a display region according to an embodiment of the present disclosure.

FIG. 45 is a cross-sectional view of Q-Q′ and R-R′ regions in FIG. 44.

FIG. 46A and FIG. 46B are enlarged cross-sectional views of a S-S′ region in FIG. 45 in a first embodiment and a second embodiment, respectively.

FIG. 47A shows a region of an electrode contact that may be formed when a partition wall of a single layer having an inverse tapered shape is formed.

FIG. 47B shows a region of an electrode contact that may be formed when a partition wall including a stack of a first partition wall structure and a second partition wall structure of an inverse tapered shape.

FIG. 48A and FIG. 48B show ΔVSS values in a case where a partition wall is present and a case in where the partition wall is absent, respectively.

FIG. 49A shows variations of an area and an electrical resistance of an electrode contact based on a width of the partition wall.

FIG. 49B shows variations of an area and an electrical resistance of an electrode contact based on a size of an open region of a bank layer.

DETAILED DESCRIPTIONS

For simplicity and clarity of illustration, elements in the figures are not necessarily drawn to scale. The same reference numbers in different figures represent the same or similar elements, and as such perform similar functionality. Further, descriptions and details of well-known steps and elements are omitted for simplicity of the description. Furthermore, in the following detailed description of the present disclosure, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. However, it will be understood that the present disclosure may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the present disclosure.

Examples of various embodiments are illustrated and described further below. It will be understood that the description herein is not intended to limit the claims to the specific embodiments described. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the present disclosure.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the present disclosure. As used herein, the singular forms “a” and “an” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises”, “comprising”, “includes”, and “including” when used in this specification, specify the presence of the stated features, integers, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, operations, elements, components, and/or portions thereof. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items. Expression such as “at least one of” when preceding a list of elements may modify the entire list of elements and may not modify the individual elements of the list.

It will be understood that, although the terms “first”, “second”, “third”, and so on may be used herein to describe various elements, components, regions, layers and/or sections, these elements, components, regions, layers and/or sections should not be limited by these terms. These terms are used to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section described below could be termed a second element, component, region, layer or section, without departing from the spirit and scope of the present disclosure.

In addition, it will also be understood that when a first element or layer is referred to as being present “on” or “beneath” a second element or layer, the first element may be disposed directly on or beneath the second element or may be disposed indirectly on or beneath the second element with a third element or layer being disposed between the first and second elements or layers.

It will be understood that when an element or layer is referred to as being “connected to”, or “coupled to” another element or layer, it may be directly on, connected to, or coupled to the other element or layer, or one or more intervening elements or layers may be present. In addition, it will also be understood that when an element or layer is referred to as being “between” two elements or layers, it may be the only element or layer between the two elements or layers, or one or more intervening elements or layers may also be present.

Further, as used herein, when a layer, film, region, plate, or the like is disposed “on” or “on a top” of another layer, film, region, plate, or the like, the former may directly contact the latter or still another layer, film, region, plate, or the like may be disposed between the former and the latter. As used herein, when a layer, film, region, plate, or the like is directly disposed “on” or “on a top” of another layer, film, region, plate, or the like, the former directly contacts the latter and still another layer, film, region, plate, or the like is not disposed between the former and the latter. Further, as used herein, when a layer, film, region, plate, or the like is disposed “below” or “under” another layer, film, region, plate, or the like, the former may directly contact the latter or still another layer, film, region, plate, or the like may be disposed between the former and the latter. As used herein, when a layer, film, region, plate, or the like is directly disposed “below” or “under” another layer, film, region, plate, or the like, the former directly contacts the latter and still another layer, film, region, plate, or the like is not disposed between the former and the latter.

Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this inventive concept belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

Hereinafter, a transparent display panel according to some embodiments of the present disclosure and a transparent display device including the same will be exemplified.

FIG. 1 is a block diagram for schematically illustrating a transparent display device according to an embodiment of the present disclosure. FIG. 2 is a plan view for schematically illustrating connection and arrangement relationships of components constituting a transparent display device.

However, each of FIG. 1 and FIG. 2 is one embodiment according to the present disclosure. Thus, the connection and arrangement relationships of the components of the transparent display device 100 according to the present disclosure are not limited thereto.

The transparent display device 100 may include a transparent display panel 110, a timing controller 140, a data driver 120, and a gate driver 130.

The transparent display panel 300 may include a display region DA containing at least one pixel P to display an image, and a non-display region NDA in which an image is not displayed.

The non-display region NDA may be disposed to surround the display region DA.

In the non-display region NDA, the gate driver 130, a data drive IC pad 310, and various lines may be disposed. The non-display region NDA may correspond to a bezel.

The transparent region of the transparent display panel 300 may be contained in both the display region DA and the non-display region NDA.

The transparent display panel 300 may include a plurality of pixel regions defined by a plurality of gate lines GL extending in a first direction, and a plurality of data lines DL extending in a second direction orthogonal to the gate lines GL.

The pixel regions may be arranged in a matrix form. Each pixel region may include a pixel P composed of at least one sub-pixel SP.

The gate driver 130 is directly stacked on the transparent display panel 110 in a form of GIP (Gate In Panel).

A plurality of GIP circuit regions may be arranged in the GIP form and may be disposed in left and right portions of the non-display region NDA respectively adjacent to left and right outer peripheral portions of the display region DA while the display region DA is interposed between the left and right portions of the non-display region NDA.

The data driver 120 may include at least one source driver integrated circuit 121 (source driver IC) to drive a plurality of data lines DL.

For example, a source driving chip corresponding to each source driver integrated circuit 121 may be mounted on a flexible film 123. One end of the flexible film 123 may be bonded to at least one control printed circuit board 150, while the other end thereof may be bonded to a data drive IC pad (DDPA) of the transparent display panel 110.

The timing controller 140 may be disposed on the control printed circuit board 150. Further, a power controller may be further disposed on the control printed circuit board 150.

In addition, a source printed circuit board may be disposed between the flexible film 123 and the control printed circuit board 150 while the source printed circuit board is connected thereto via a connection medium such as a flexible flat cable (FFC) or a flexible printed circuit (FPC).

In one example, the transparent display device 100 may be embodied as a liquid crystal display device, an organic light-emitting display device, etc. However, the present disclosure is not limited thereto. Hereinafter, in accordance with an embodiment of the present disclosure, an example in which the transparent display device 100 may be embodied as an organic light-emitting display device will be described with reference to FIG. 3 and FIG. 4.

The transparent display panel may include a first substrate 200 and a second substrate 270.

The first substrate 200 may act as a base substrate including a display region DA in which pixels are disposed, and a non-display region NDA.

The second substrate 270 may be opposite to the first substrate 200 and may act as an encapsulating substrate.

Each of the first substrate 200 and the second substrate 270 may be embodied as a plastic substrate or a glass substrate.

The display region DA of the first substrate 200 includes a light-emitting region EA and a transmissive region TA.

A plurality of sub-pixels may be arranged in the light-emitting region EA.

Each sub-pixel may be a red sub-pixel emitting red light, or may be a green sub-pixel emitting green light, or may be a blue sub-pixel emitting blue light, or may be a sub-pixel emitting light, for example, white light other than the red, green or blue light.

Each sub-pixel may include a light-emitting region EA for emitting light of a corresponding color, and a circuit region electrically connected to the light-emitting region EA to control light-emission from the light-emitting region EA.

The light-emitting region of the sub-pixel EA may refer to a region in which light of a corresponding color to each sub-pixel is emitted or may refer to a pixel electrode such as an anode electrode that exists in each sub-pixel, or may mean a region where the pixel electrode is disposed.

The light-emitting region EA includes an organic light-emitting element 220 including an anode electrode as a first electrode 221, an organic light-emitting layer 223, and a cathode electrode as a second electrode 225. The organic light-emitting element 220 emits light at a predefined brightness using a voltage supplied to the first electrode 221 and a voltage supplied to the second electrode 225.

In this case, the second electrode 225 as a transparent electrode may extend across both the light-emitting region EA and the transmissive region TA.

The circuit region of the sub-pixel means a circuit region including the driving thin-film transistor 210 that supplies a voltage or a current to the pixel electrode of each sub-pixel to control light emission from the light-emitting region EA or may mean a region in which the circuit region is disposed.

The driving thin-film transistor 210 includes a gate electrode 214, a source electrode 217 a, a drain electrode 217 b and an active layer 212.

When the circuit region receives a gate signal from the gate line GL using the thin-film transistors, the circuit region may supply a predefined voltage to the first electrode 221 of the organic light-emitting element 220 of the light-emitting region EA based on a data voltage of the data line DL.

The circuit region may vertically at least partially overlap the light-emitting region EA, but may be disposed at an opposite side to a side from which light is emitted so as not to interfere with the light emission.

An encapsulating layer 250 is formed on the organic light-emitting element 220, specifically, the second electrode 225 thereof. A color filter 260 corresponding to the organic light-emitting element 220 may be formed on the encapsulating layer 250.

The color filter 260 may have the same color as or a different color from that of a corresponding sub-pixel.

The transmissive region TA refers to a region that transmits incident light, and may be a region excluding the circuit region. A transmittance of the transparent display device depends on an area of the transmissive region TA.

FIG. 3 shows one embodiment of the present disclosure in which the light-emitting region EA and the transmissive region TA corresponds to one sub-pixel. However, the present disclosure is not limited thereto. The arrangement form of the light-emitting region EA and the transmissive region TA of the transparent display device according to the present disclosure is not limited thereto. FIG. 4 is a more detailed cross-sectional view of a light-emitting region EA corresponding to one sub-pixel in an organic light-emitting display device according to an embodiment of the present disclosure.

Over the first substrate 200, a driving thin-film transistor 210, and an organic light-emitting element 220 are disposed. A buffer layer 201 may be formed on the first substrate 200, and a gate insulation layer 213 may be formed on the active layer 213, and an interlayer insulation layer 216 may be formed on the gate electrode 214.

More specifically, as shown in FIG. 4, a buffer layer 201 is formed on the first substrate 200, a gate insulating layer 213 is formed on the buffer layer 201 to cover an active layer 212 of the driving thin-film transistor 210, and an interlayer insulating layer 216 is formed on the gate insulating layer 213 to cover a gate electrode 214 of the driving thin-film transistor 210.

A passivation layer 218 may be formed on the driving thin-film transistor 210 to cover the driving thin-film transistor 210. A contact-hole exposing a drain electrode 217 b may be formed in the passivation layer 218.

The passivation layer 218 may act as a planarization layer made of an organic insulating material.

The first electrode 221 constituting the organic light-emitting element 220 is formed on the passivation layer 218. The first electrode 221 is electrically connected to the drain electrode 217 b via the contact-hole defined in the passivation layer 218. Thus, the driving thin-film transistor 210 and the first electrode 221 may be electrically connected to each other.

The first electrode 221 may act as an anode electrode that serves to inject holes. In this case, the first electrode may be embodied as a transparent electrode made of at least one transparent conductive material such as indium tin oxide (ITO), antimony tin oxide (ATO), and indium zinc oxide (IZO).

A bank layer 231 is formed on and over the passivation layer 218. Sub-pixels may be separated from each other via the bank layer 231 to form a border between adjacent light-emitting region EAs to render corresponding colors, respectively. The bank layer 231 may have a bank-hole defined therein corresponding to a sub-pixel region to partially expose the first electrode 221.

The organic light-emitting layer 223 may be formed on a top face of the bank layer 231 and on a top face of a portion of the first electrode 221 exposed through the bank-hole. A region where the organic light-emitting layer 223 contacts the first electrode 221 may correspond to a sub-pixel region, more specifically, the light-emitting region EA.

The organic light-emitting layer 223 may include a hole injection layer (HIL), a hole transport layer (HTL), a light-emitting layer (EML), an electron transport layer (ETL), an electron injection layer (EIL).

The light-emitting layer (EML) may emit red R, green G or blue B light and may be made of a phosphorescent material or a fluorescent material that emits a corresponding color.

In this case, each of the hole injection layer (HIL), the hole transport layer (HTL), the electron transport layer (ETL), and the electron injection layer (EIL) may occupy an entire display region. The light-emitting layer EML may be patterned to correspond to each color region, specifically, the first electrode 221. Further, each of the hole injection layer (HIL), the hole transport layer (HTL), the electron transport layer (ETL), and the electron injection layer (EIL) may be patterned to correspond to each color region, specifically, the first electrode 221.

In some embodiments, the second electrode 225 is formed on the organic light-emitting layer 223 and over an entirety of the first substrate 200. The second electrode 225 is disposed on an entirety of the display region DA of the first substrate 200. In this case, the second electrode 225 may be disposed on an entirety of the display region DA except for the transmissive region TA.

The second electrode 225 may act as a cathode electrode that serves to inject electrons.

In this case, the second electrode 225 may include at least one of materials such as Ca, Al:Li, Mg:Ag, and Ag. Further, the second electrode 225 may be embodied as a transparent electrode made of at least one of transparent conductive materials such as indium tin oxide (ITO), antimony tin oxide (ATO), and indium zinc oxide (IZO).

On the organic light-emitting element 220, an encapsulating layer 250 is formed that prevents external moisture from penetrating the organic light-emitting element 220.

On the encapsulating layer 250, the second substrate 270 as the encapsulating substrate opposite to the first substrate 200 may be formed.

In this case, a barrier layer may be formed between the encapsulating layer 250 and the second substrate 270 to more effectively prevent external moisture or oxygen from penetrating the organic light-emitting element 220.

FIG. 5 shows a connection relationship of line connection pads disposed on the first substrate 301 in the transparent display panel 300 according to an embodiment of the present disclosure.

The first substrate 301 includes a display region DA and a non-display region NDA disposed to surround the display region DA. The non-display region NDA may surround top, bottom, left, and right sides of the display region DA. A vertical or up-down direction of the display region DA refers to a Y-axis direction, while a horizontal or left-right direction of the display region DA refers to a X-axis direction.

The display region DA may have a rectangular shape including long sides and short sides.

In this case, the long side is relatively longer than the short side.

Further, the long side means a side parallel to the X-axis direction as the left and right direction of the display region DA.

The short side means a side parallel to the Y-axis direction as the vertical or up-down direction of the display region DA.

The gate driver 130 may be disposed in a form of GIP (gate in panel) and on at least one side to the display region DA.

In other words, a pair of GIP circuit regions 360 are disposed in portions of the non-display region NDA located on the left and right sides to the display region DA respectively.

For example, the GIP circuit region 360 is disposed along the short side of the display region DA. A first VSS voltage line 321 and a second VSS voltage line 322 may be disposed along the long side of the display region DA.

On one portion of the non-display region NDA where the GIP circuit region 360 is disposed, a GIP ESD (electro-static discharge) protection circuit region 365 that operates when static electricity is introduced into the GIP circuit region 360 to reduce or minimize static electricity inflow may be disposed.

At least one data drive IC pad 310 may be disposed on one side to the display region DA where the GIP circuit region 360 is not disposed, for example, at a portion of the non-display region NDA above a top long side of the display region DA.

The data drive IC pad 310 is connected to various lines necessary for driving the transparent display panel 300 such as the power line and the data line.

Between the data drive IC pad 310 and the display region DA, a data line connection pad 311, a reference voltage line connection pad 340, a VSS voltage line connection pad 320, and a VDD voltage line connection pad 330 are disposed to be connected to each other via the data drive IC pad 310 and various lines.

Specifically, each of right and left reference voltage line connection pads 340, each of right and left VDD voltage line connection pads 330, and each of right and left VSS voltage line connection pads 320 may be disposed adjacent to each of right and left portions of the data drive IC pad 310. A spacing between each of right and left reference voltage line connection pads 340 and a length direction center of the data drive IC pad 310 is smaller than a spacing between each of right and left VDD voltage line connection pads 330 and the length direction center of the data drive IC pad 310 which is smaller than a spacing between each of right and left VSS voltage line connection pads 320 and the length direction center of the data drive IC pad 310.

That is, the both reference voltage line connection pads 340, the both VDD voltage line connection pads 330, and the both VSS voltage line connection pads 320 may be arranged symmetrically to each other around a center of the data line connection pad 311. In one or more embodiments, the term “symmetrically” used throughout in the specification is used to include the meaning of both symmetrically and substantially symmetrically.

The reference voltage line connection pad 340, the VDD voltage line connection pad 330, and the VSS voltage line connection pad 320 are arranged to be spaced apart from each other.

The VDD voltage line connection pad 330 may act as a high-level voltage power line connection pad that supplies high-level voltage power to a pixel for driving the pixel, while the VSS voltage line connection pad 320 may act as a low-level voltage power line connection pad that applies low-level voltage power to the pixel for driving the pixel.

The reference voltage line connection pad 340 may supply a reference voltage Vref to a pixel.

A reference voltage line 341 electrically connected to the reference voltage line connection pad 340, a first VDD voltage line 331 electrically connected to the VDD voltage line connection pad 330, and a first VSS voltage line 321 electrically connected to the VSS voltage line connection pad 320 may be disposed between the reference voltage line connection pad 340 and the display region DA, between the VDD voltage line connection pad 330 and the display region DA, and between the VSS voltage line connection pad 320 and the display region DA, respectively.

In one embodiment of the present disclosure, the VDD voltage line connection pad 330 and the first VDD voltage line 331 are integrally formed with each other, the reference voltage line connection pad 340 and the reference voltage line 341 are formed to be spaced apart from each other and electrically connected to each other via a separate connection electrode, and the VSS voltage line connection pad 320 and the first VSS voltage line 321 are formed to be spaced apart from each other and electrically connected to each other via a separate connection electrode. However, the present disclosure is not limited thereto.

The first VDD voltage line 331 may be formed to have a bar shape, and may extend parallel to one side face of the display region DA, specifically, along the long side of the display region DA and may be integrally formed with the VDD voltage line connection pad 330. In one or more embodiments, a bar shape may include a rectangular bar shape, an elongated bar shape or even a bar shape closer to a square bar shape, or any other suitable shape for being implemented in a display device.

Further, the first VDD voltage line 331 may be formed integrally with a plurality of VDD voltage line connection pads 330 corresponding to each data drive IC pad 310 to electrically connect the plurality of VDD voltage line connection pads 330 to each other.

The reference voltage line 341 may be disposed between the first VDD voltage line 331 and the display region DA. In one embodiment of the present disclosure, an example in which the reference voltage line may act as the initial voltage line will be described. However, the present disclosure is not limited thereto. Depending on a compensation circuit region, the reference voltage line 341 may act as a separate line from the initial voltage line.

Thus, the reference voltage line connection pad 340 may be disposed to be spaced apart from the reference voltage line 341 in the Y direction while a spacing between the former and the display region DA is larger than a spacing between the latter and the display region DA.

The reference voltage line 341 may be formed to have a bar shape, and may extend parallel to the first VDD voltage line 331.

In order to apply the reference voltage to the reference voltage line 341, the reference voltage line connection pad 340 and the reference voltage line 341 may be electrically connected to each other via a second connection electrode 352 as a separate connection electrode.

The first VSS voltage line 321 may be disposed between the reference voltage line 341 and the display region DA.

Thus, the VSS voltage line connection pad 320 may be disposed to be spaced apart from the first VSS voltage line 321 in the Y direction while a spacing between the former and the display region DA is larger than a spacing between the latter and the display region DA.

The first VSS voltage line 321 may be formed to have a bar shape and may extend in parallel with the first VDD voltage line 331 and the reference voltage line 341.

In order to apply the VSS voltage to the first VSS voltage line 321, the VSS voltage line connection pad 320 and the first VSS voltage line 321 may be electrically connected to each other via a first connection electrode 351 as a separate connection electrode.

Further, a VSS voltage auxiliary line connection pad 326 as a separate portion from the VSS voltage line connection pad 320 may be disposed between the left and right reference voltage line connection pads 340.

Specifically, the VSS voltage auxiliary line connection pad 326 may have a form of an island spaced from and disposed between the left and right reference voltage line connection pads 340 and spaced from and disposed between the data line connection pad 311 and the VDD voltage line.

The VSS voltage auxiliary line connection pad 326 may be electrically connected to the first VSS voltage line 321 via the first connection electrode 351.

In this way, when the VSS voltage auxiliary line connection pad 326 is electrically connected to the first VSS voltage line 321 via the first connection electrode 351, an entire contact area of the first VSS voltage line 321 is enlarged, thereby to keep a resistance distribution of the first VSS voltage line 321 uniform while lowering an overall resistance thereof.

An ESD protection circuit region 371 may be disposed between the reference voltage line 341 and the display region DA. A multiplexer (MUX) circuit region 373 may be disposed between the first VSS voltage line 321 and the display region DA. However, the present disclosure is not limited thereto. The positions of ESD protection circuit region 371 and MUX circuit region 373 may vary based on a design scheme of the transparent display panel 300. Further, in some embodiments, the MUX circuit region 373 may be disposed between the first VSS voltage line 321 and a dummy pixel pattern region DPA that is adjacent to the display region DA (see FIG. 36).

The ESD protection circuit region 371 may include a plurality of thin-film transistors constituting an ESD protection circuit. When static electricity is generated from the transparent display panel 300, the ESD protection circuit region operates to take out static electricity to an outside.

The MUX circuit region 373 may be configured to include a plurality of thin-film transistors constituting a MUX circuit.

When using the MUX circuit region 373, one channel of a driver IC output may supply a signal to two or more data lines 313. This has an advantage of reducing the number of driver ICs as used.

Each of the ESD protection circuit region 371 and the MUX circuit region 373 may be formed in a bar shape extending parallel to the reference voltage line 341 and the like. However, the present disclosure is not limited thereto.

The first VDD voltage line 331 and the first VSS voltage line 321 may be disposed in an upper portion of the non-display region NDA adjacent to an upper side of the display region DA, while a second VDD voltage line 332 and a second VSS voltage line 322 may be disposed in a lower portion of the non-display region NDA adjacent to a lower side of the display region DA.

The second VDD voltage line 332 and the second VSS voltage line 322 may be spaced from each other while a spacing between the former and the display region DA is smaller than a spacing between the latter and the display region DA.

The second VDD voltage line 332 may be formed to have a bar shape, and may extend in parallel along one side face of the display region DA, specifically, along the long side of the display region DA.

In order to apply the VDD voltage to the second VDD voltage line 332, the first VDD voltage line 331 and the second VDD voltage line 332 may be electrically connected to each other via a separate connection electrode as a VDD voltage connection line 333.

Therefore, using the connection structure as described above, the VDD voltage supplied via the VDD voltage line connection pad 330 may be applied to the second VDD voltage line 332 via the first VDD voltage line 331 and the VDD voltage connection line 333.

In this case, at least one VDD voltage connection line 333 is disposed in the display region DA to extend across the display region DA and thus electrically connects the first VDD voltage line 331 and the second VDD voltage line 332 to each other.

In one example, the second VSS voltage line 322 may be formed to have a bar shape, and may extend in parallel along one side face of the display region DA, specifically, along the long side of the display region DA.

A width W₂ of the second VSS voltage line 322 may be smaller than a width W₁ of the first VSS voltage line 321, such that the second VSS voltage line 322 is thinner than the first VSS voltage line 321.

In order to apply the VSS voltage to the second VSS voltage line 322, the first VSS voltage line 321 and the second VSS voltage line 322 may be electrically connected to each other via a separate connection electrode as a VSS voltage connection line 323.

Therefore, using the connection structure as described above, the VSS voltage supplied via the VSS voltage line connection pad 320 may be applied to the second VSS voltage line 322 via the first VSS voltage line 321 and the VSS voltage connection line 323.

In this case, at least one VSS voltage connection line 323 may be disposed in the display region DA to extend across the display region DA and thus electrically connects the first VSS voltage line 321 and the second VSS voltage line 322 to each other.

As in one embodiment of the present disclosure, the first VSS voltage line 321 and the second VSS voltage line 322 disposed above and below the display region DA may be electrically connected to each other via at least one VSS voltage connection line 323 extending across the display region DA. Thus, following effects may be realized.

First, non-transparent VSS voltage lines located at left and right portions of the non-display region on the left and right sides to the display region DA may be omitted. Thus, the transparent region of the bezel may be enlarged, so that the transparent region in the bezel may be increased or maximized.

Further, non-transparent VSS voltage lines located at left and right portions of the non-display region on the left and right sides to the display region DA may be omitted. Thus, the VSS voltage line-connection regions required to allow the VSS voltage lines to be placed on bezel portions left and right to the display region DA are not needed. Thus, the bezel may be slim.

For example, when the VSS voltage connection line 323 is disposed in each of left and right portions of the non-display region NDA left and right to the display region DA, the VSS voltage line is disposed to surround the display region DA and extends along an outer periphery of the display region DA. In this case, a size of the transparent region of the bezel is reduced because the non-transparent VSS voltage line is formed in the non-display region NDA out of the outer periphery of the display region DA, thereby to disallow reduction of the bezel area.

However, in the VSS voltage line arrangement structure according to an embodiment of the present disclosure, the VSS voltage lines are not disposed on the top, bottom, left, and right sides to the display region DA, that is, on four side portions of the bezel. Rather, it may suffice that the VSS voltage lines are disposed only on top and bottom side portions of the bezel up and down to the display region DA.

Therefore, according to an embodiment of the present disclosure, a maximum of a transparent region of a bezel where the non-transparent VSS voltage line is not disposed may be secured. When necessary, a size of the bezel may be reduced, so that the bezel may be slimmer.

Further, when the VSS voltage line surrounds the outer periphery of the display region DA, the VSS voltage flows around the outer periphery of the display region DA and flows into the display region DA and then is supplied to the pixels in the display region DA. Thus, the VSS voltage line which serves as a current path must be thick in order to function as the current path in a reliable manner in terms of the electrical resistance.

However, in one embodiment of the present disclosure, while the VSS voltage connection line 323 passes across the display region DA, the VSS voltage connection line may directly supply the VSS voltage to the pixel. Thus, the second VSS voltage line 322 may not serve as a current path.

In this way, when the second VSS voltage line 322 does not serve as the current path, the second VSS voltage line 322 does not need to be formed to be thick in consideration of the electrical resistance and thus be as thin as possible.

Therefore, according to an embodiment of the present disclosure, the second VSS voltage line 322 may have a width smaller than that of the first VSS voltage line 321. Thus, as the width of the second VSS voltage line 322 decreases, a size of a transparent region in a lower bezel portion below the display region DA may be increased. When necessary, the bezel may be made slimmer.

A lighting tester 375 may be disposed in the non-display region NDA and be spaced apart from the second VSS voltage line 322 while a spacing between the former and the display region DA is larger than a spacing between the latter and the display region DA.

The lighting tester 375 may be formed in a bar shape extending parallel to the second VSS voltage line 322, and may further extend along both left and right sides of the display region DA, thereby to surround three sides of the display region DA.

The lighting tester 375 may supply a lighting test signal to a plurality of data lines 313 before a module process after the transparent display panel 300 is manufactured and may inspect a defect of the transparent display panel 300.

The lighting tester 375 includes a plurality of inspection switching elements connected to the plurality of data lines 313 respectively.

Therefore, the plurality of data lines 313 branched from the data line connection pad 311 extend across the display region DA and then are electrically connected to the lighting tester 375.

A lighting test signal applicator 376 may be formed on a partial region of each of the reference voltage line connection pad 340, the VDD voltage line connection pad 330, and the VSS voltage line connection pad 320 to supply the lighting test signal to the lighting tester 375.

FIG. 6 to FIG. 10 are plan views showing, based on an interlayer stacking structure, a connection relationship between the lines of FIG. 5 in the transparent display panel 300 according to an embodiment of the present disclosure.

As shown in FIG. 6, the reference voltage line connection pad 340, the VDD voltage line connection pad 330, the VSS voltage line connection pad 320, the VSS voltage auxiliary line connection pad 326, the reference voltage line 341, the first VDD voltage line 331, the second VDD voltage line 332, the first VSS voltage line 321 and the second VSS voltage line 322 of the transparent display panel 300 according to an embodiment of the present disclosure may constitute the same layer and may be spaced apart from each other. In some embodiments where appropriate, constitute the same layer means that the elements (or components) are formed of the same layer (or in some cases are formed on the same layer).

The reference voltage line connection pad 340, the VDD voltage line connection pad 330, the VSS voltage line connection pad 320, the VSS voltage auxiliary line connection pad 326, the reference voltage line 341, the first VDD voltage line 331, the second VDD voltage line 332, the first VSS voltage line 321, the second VSS voltage line 322, the source electrode 217 a, and the drain electrode 217 b of the driving thin-film transistor 210 of a pixel may be made of the same material and may constitute the same layer.

However, as illustrated above, the VDD voltage line connection pad 330 and the first VDD voltage line 331 may be integrally formed with each other without being separated from each other.

Thus, the line connection pads and the lines constitute the same layer. Thus, the connection electrodes that electrically connect the line connection pads and the lines to each other should not form a short-circuit with other lines between the line connection pad and the line to be connected to each other, or between the lines.

For example, in order to connect the data lines 313 branched from the data line connection pad 311 to the lighting tester 375, the data line 313 may be composed of a first data line 314 and a second data line 315 which constitute different layers and are electrically connected to each other.

In this case, the first data line 314, the source electrode 217 a, and drain electrode 217 b of the driving thin-film transistor 210 of the pixel may constitute the same layer and may be made of the same material. The second data line 315, and the gate electrode 214 of the driving thin-film transistor 210 of the pixel may constitute the same layer and may be made of the same material.

The data line 313 applies a data signal to pixels in the display region DA. Thus, the first and second data lines 314 and 315 of the data line 313 branched from the data line connection pad 311 may constitute different layers so as not to form a short-circuit with various line connection pads and lines disposed in a region between the display region DA and the data line connection pad 311.

Thus, the second data line 315 may act as the data line 313 in a region between the display region DA and the data line connection pad 311. The first data line 314 constituting a different layer from a layer of the second data line 315 may act as the data line 313 in the display region.

Then, the second data line 315 may act as the data line 313 in a region between the display region DA and the lighting tester 375. Then, the first data line 314 as the data line 313 may be connected to the lighting tester 375.

However, the first data line 314 and the second data line 315 may act as the data line 313 in a repeatedly alternate manner such that the data line 313 does not form a short-circuit with the second VDD voltage line 332 and the second VSS voltage line 322 in regions in which the data line 313 overlaps the second VDD voltage line 332 and the second VSS voltage line 322 in a region between the display region DA and the lighting tester 375.

The data line 313 may change from the first data line 314 to the second data line 315 in a region where the data line 313 does not overlap the second VDD voltage line 332, such that the data line 313 does not form a short-circuit with the second VDD voltage line 332 while extending across the second VDD voltage line 332. In this way, the second data line 315 and the second VDD voltage line 332 do not constitute the same layer, thereby preventing the short circuit therebetween.

In the connection, the data line 313 changing from the first data line 314 to the second data line 315 may mean that, as shown in FIG. 12, the first data line 314 is connected to the second data line 315 via at least one contact-hole such that electrical connection therebetween is maintained, but the first data line 314 and the second data line 315 constitute different layers and are made of the different materials. This principle may be equally applied to other lines as exemplified below.

After the second data line 315 extends across the second VDD voltage line 332, the second data line may be changed back to the first data line 314 in a region where the data line 313 does not overlap the second VDD voltage line 332.

That is, the first data line 314 and the second data line 315 may constitute different layers and are electrically connected to each other via at least one second data line contact-hole 315 h.

In the same manner, the reference voltage connection line 343 may be composed of a first reference voltage connection line 344 and a second reference voltage connection line 345 which constitute different layers and are electrically connected to each other.

In this case, the first reference voltage connection line 344, the source electrode 217 a and the drain electrode 217 b may constitute the same layer and may be made of the same material. The second reference voltage connection line 345 and the gate electrode 214 may constitute the same layer and may be made of the same material.

For example, the reference voltage connection line 343 extends to a lower end of the display region DA. The reference voltage connection line 343 may be composed of the first reference voltage connection line 344 and the second reference voltage connection line 345 which constitute different layers and are electrically connected to each other. The reference voltage connection line 343 extends across the display region DA. A distal end of the reference voltage connection line 343 need not contact a separate line.

Because the reference voltage connection line 343 applies a reference voltage to pixels in the display region DA, the reference voltage connection line 343 is composed of different reference voltage connection lines constituting different layers such that the reference voltage connection line 343 does not form a short-circuit with various line connection pads and lines in a region between the display region DA and the reference voltage line 341.

Thus, the reference voltage connection line 343 is embodied as the second reference voltage connection line 345 in a region between the display region DA and the reference voltage line 341. In the display region DA, the reference voltage connection line 343 is embodied as the first reference voltage connection line 344 which constitutes a different layer from that of the second reference voltage connection line 345.

The first reference voltage connection line 344 and the second reference voltage connection line 345 may constitute different layers and may be electrically connected to each other via at least one contact-hole. Further, the VSS voltage connection line 323 may be composed of a first VSS voltage connection line 324 and a second VSS voltage connection line 325 constituting different layers and being electrically connected to each other.

In this case, the first VSS voltage connection line 324, the source electrode 217 a and drain electrode 217 b may constitute the same layer and may be made of the same material. The second VSS voltage connection line 325 and the gate electrode 214 may constitute the same layer and may be made of the same material.

For example, in order to connect the VSS voltage connection line 323 to the second VSS voltage line 322, the first VSS voltage connection line 324 and the second VSS voltage connection line 325 constituting different layers are electrically connected to each other.

Since the VSS voltage connection line 323 electrically connects the first VSS voltage line 321 and the second VSS voltage line 322 sandwiching the display regions DA therebetween to each other, the first VSS voltage connection line 324 and the second VSS voltage connection line 325 of the VSS voltage connection line may constitute different layers such that the VSS voltage connection line does not form a short-circuit with various line connection pads and lines in a region between the first VSS voltage line 321 and the second VSS voltage line 322.

In one embodiment of the present disclosure, no other line is disposed between the display region DA and the first VSS voltage line 321. Thus, the VSS voltage connection line 323 extending from the first VSS voltage line 321 may be embodied as the first VSS voltage connection line 324 integrally formed with the first VSS voltage line 321 and made of the same material as that of the first VSS voltage line 321 and constituting the same layer with the first VSS voltage line 321.

The first VSS voltage connection line 324 branched from the first VSS voltage line 321 may extend across the display region DA. Then, when the VSS voltage connection line 323 extends across the second VDD voltage line 332, the first VSS voltage connection line 324 and the second VSS voltage connection line 325 may act as the VSS voltage connection line 323 in a repeatedly alternate manner such that the VSS voltage connection line 323 does not form a short-circuit with the second VDD voltage line 332 in a region where the VSS voltage connection line 323 overlaps the second VDD voltage line 332.

When the VSS voltage connection line 323 extends across the second VDD voltage line 332, the VSS voltage connection line 323 may change from the first VSS voltage connection line 324 to the second VSS voltage connection line 325 in a region where the VSS voltage connection line 323 does not overlap the second VDD voltage line 332. Thus, when the VSS voltage connection line 323 extends across the second VDD voltage line 332, the VSS voltage connection line 323 does not form a short-circuit with the second VDD voltage line 332.

That is, the first VSS voltage connection line 324 and the second VSS voltage connection line 325 constitute different layers and are electrically connected to each other via at least one second VSS voltage connection line contact-hole 325 h.

After the VSS voltage connection line 323 has extended across the second VDD voltage line 332, the first VSS voltage connection line 324 may be connected to the second VSS voltage line 322, as shown in FIG. 13.

In this case, the first VSS voltage connection line 324 and the second VSS voltage line 322 may be electrically connected to each other via a second VSS voltage connection line 325 connected to the first VSS voltage connection line 324 via at least one second VSS voltage connection line contact-hole 325 h.

In addition, in a region where the second VSS voltage line 322 does not overlap the data line 313, auxiliary lines 327 connected to the second VSS voltage line 322 via at least one auxiliary line contact-hole 327 h are disposed below the second VSS voltage line 322.

The auxiliary line 327 and the gate electrode 214 may be made of the same material and may constitute the same layer.

The auxiliary line 327 may be connected to a rear face of the second VSS voltage line 322, thereby reducing an overall resistance of the second VSS voltage line 322.

Further, the VDD voltage connection line 333 may be composed of a first VDD voltage connection line 334 and a second VDD voltage connection line 335 constituting different layers and being electrically connected to each other.

In this case, the first VDD voltage connection line 334, the source electrode 217 a and drain electrode 217 b of the driving thin-film transistor 210 of the pixel may be made of the same material and may constitute the same layer. The second VDD voltage connection line 335 and the gate electrode 214 of the driving thin-film transistor 210 of the pixel may be made of the same material and may constitute the same layer.

For example, in order to connect the VDD voltage connection line 333 to the second VDD voltage line 332, the first VDD voltage connection line 334 and the second VDD voltage connection line 335 constitute different layers and are electrically connected to each other.

The VDD voltage connection line 333 electrically connects the first VDD voltage line 331 and the second VDD voltage line 332 sandwiching the display regions DA therebetween to each other. Thus, the first VDD voltage connection line 334 and the second VDD voltage connection line 335 constitute different layers so that the VDD voltage connection line 333 does not form a short-circuit with various line connection pads and lines in a region between the first and second VDD voltage lines 331 and 332.

Thus, the VDD voltage connection line 333 may be embodied as the first VDD voltage connection line 334 in a region between the first VDD voltage line 331 and the display region DA. When the VDD voltage connection line 333 extends across the display region DA, the VDD voltage connection line 333 may be embodied as the second VDD voltage connection line 335. That is, the VDD voltage connection line 333 changes from the first VDD voltage connection line 334 to the second VDD voltage connection line 335.

That is, the first VDD voltage connection line 334 and the second VDD voltage connection line 335 constitute different layers and are electrically connected to each other via at least one contact-hole.

Then, the VDD voltage connection line 333 may be embodied as the first VDD voltage connection line 334 which may be connected to the second VDD voltage line 332, as shown in FIG. 12, in a region between the display region DA and the second VDD voltage line 332.

In this case, the first VDD voltage connection line 334 and the second VDD voltage line 332 may be electrically connected to each other via the second VDD voltage connection line 335 connected to the first VDD voltage connection line 334 via at least one second VDD voltage connection line contact-hole 335 h.

In addition, auxiliary lines 327 connected to the second VDD voltage line 332 via at least one contact-hole may be disposed in a region where the second VDD voltage line 332 does not overlap the data line 313 and VSS voltage connection line 323.

The auxiliary line 327 and the gate electrode 214 may be made of the same material and may constitute the same layer.

The VDD voltage auxiliary line 327 may be connected to a rear face of the second VDD voltage line 332 to reduce an overall resistance of the second VDD voltage line 332.

FIG. 7 additionally shows a passivation-hole formed in the passivation layer 218. FIG. 8 further shows a first connection electrode 351 connecting the VSS voltage line connection pad 320 and the first VSS voltage line 321 to each other, and a second connection electrode 352 connecting the reference voltage line connection pad 340 and the reference voltage line 341 to each other.

The passivation layer 218 may be formed on the reference voltage line connection pad 340, the VDD voltage line connection pad 330, the VSS voltage line connection pad 320, the reference voltage line 341, the first VSS voltage line 321, the second VSS voltage line 322, the first VDD voltage line 331, and the second VDD voltage line 332. The passivation layer 218 may act as a planarization layer made of an organic material layer such as PAC.

Further, the passivation layer 218 serves as an insulating layer. Thus, for electrical connection between the line connection pads and the lines, a passivation-hole, that is, a planarization-hole may be formed in portions of each line connection pad and each line.

The passivation-hole means not only a contact-hole, but also an open hole formed by partially removing the passivation layer 218 to secure a contact area as much as possible. Each line connection pad and each line may be electrically connected to each other via the connection electrodes connected to each other via the passivation-hole.

In FIG. 7, in order to clarify distinction between the layers, the passivation layer 218 is not shown separately, but only a region where the passivation-hole is formed is shown in an emphasis manner.

A first passivation-hole 218 a is formed on the VSS voltage line connection pad 320 and the first VSS voltage line 321. The first connection electrode 351 electrically connects the VSS voltage line connection pad 320 and the first VSS voltage line 321 to each other via the first passivation-hole 218 a, as shown in FIG. 8 and FIG. 14.

In other words, in order to prevent a short circuit between the VSS voltage line connection pad 320 and the first VSS voltage line 321 and the first VDD voltage line 331 and the reference voltage line 341 disposed between the VSS voltage line connection pad 320 and the first VS S voltage line 321, a jumping connection structure of an electrode to connect the VSS voltage line connection pad 320 and the first VSS voltage line 321 to each other may be beneficial.

Therefore, according to an embodiment of the present disclosure, the passivation layer 218 is formed on the first VDD voltage line 331 and the reference voltage line 341. The first passivation-hole 218 a is formed on the VSS voltage line connection pad 320 and the first VSS voltage line 321.

Thus, the jumping connection structure of the electrode may be formed using the first connection electrode 351 which is formed on the passivation layer 218 and whose one portion is connected to the VSS voltage line connection pad 320 via one first passivation-hole 218 a and whose an opposite portion is connected to the first VSS voltage line 321 via an opposite first passivation-hole 218 a.

The first connection electrode 351 and the anode electrode as the first electrode 221 constituting the organic light-emitting element 220 may be made of the same material and may constitute the same layer.

The first connection electrode 351 electrically connects the VSS voltage line connection pad 320 and the first VSS voltage line 321 to each other and, to this end, is preferably formed to have a large area as much as possible in order to reduce or minimize electrical resistance and to increase or maximize uniformity of the resistance distribution.

Therefore, the first connection electrode 351 may be formed to extend over the first VDD voltage line 331, the reference voltage line 341, and the first VSS voltage line 321, and thus may be formed to have an increased area or a maximum area.

However, the first connection electrode 351 does not extend over all regions of the first VDD voltage line 331 and the reference voltage line 341 and the first VSS voltage line 321. The first connection electrode 351 does not extend over a partial region such as a region of the second connection electrode 352 as described later or a spacing region between the first and second connection electrodes 351 and 352.

Further, in ordered to increase or maximize a contact area of the first passivation-hole 218 a with the VSS voltage line connection pad 320 and the first VSS voltage line 321, the first passivation-hole 218 a may have a shape corresponding to the first VSS voltage line 321, that is, a long bar shape (e.g., an elongated bar shape).

Further, at least one gas exhaust hole 355 may be formed in at least a partial region of the first connection electrode 351 as shown in FIG. 14.

The gas exhaust hole 355 serves to discharge unnecessary gases that may be generated during a process of forming the transparent display panel 300. Thus, when forming the gas exhaust hole 355 in the first connection electrode 351 having a large area, reliability of the transparent display panel 300 may be further enhanced.

The bank layer 231 formed on the first connection electrode 351 has open regions defined therein corresponding to the gas exhaust holes 355 to secure a passage of the gas exhaust hole 355. Each bank layer 231 may define a boundary between adjacent gas exhaust holes 355.

Further, a VSS voltage auxiliary line connection pad 326 may be additionally disposed and may be electrically connected to the first VSS voltage line 321 via the first connection electrode 351.

The VSS voltage auxiliary line connection pad 326 and the VSS voltage line connection pad 320 may be made of the same material and constitute the same layer. However, the VSS voltage auxiliary line connection pad 326 has an island form separated from the VSS voltage line connection pad 320 and not connected to a separate line.

The first passivation-hole 218 a is formed on the VSS voltage auxiliary line connection pad 326 such that the VSS voltage auxiliary line connection pad 326 is connected to the first connection electrode 351 via the first passivation-hole 218 a, thereby increasing a total area of the first connection electrode 351, thereby reducing the overall resistance and making the resistance distribution more uniform.

In one example, the passivation layer 218 is formed on the reference voltage line connection pad 340 and the reference voltage line 341. The second connection electrode 352 electrically connects the reference voltage line connection pad 340 and the reference voltage line 341 to each other via a second passivation-hole 218 b as shown in FIG. 8 and FIG. 14.

In order to prevent a short circuit between the reference voltage line connection pad 340 and the reference voltage line 341 and the first VDD voltage line 331 between the reference voltage line connection pad 340 and the reference voltage line 341, a jumping structure of an electrode for connecting the reference voltage line connection pad 340 and the reference voltage line 341 to each other is required.

Therefore, according to an embodiment of the present disclosure, the passivation layer 218 is formed on the first VDD voltage line 331, and the second passivation-hole 218 b is formed on each of the reference voltage line connection pad 340 and the reference voltage line 341, as shown in FIG. 7.

Thus, the jumping connection structure of an electrode may be formed using the second connection electrode 352 which is formed on the passivation layer 218 and whose one portion is connected to the reference voltage line connection pad 340 via one second passivation-hole 218 b and whose an opposite portion is connects to the reference voltage line 341 via an opposite second passivation-hole 218 b.

The second connection electrode 352 and the first connection electrode 351 may be made of the same material and may constitute the same layer but may be spaced apart from each other. Thus, the second connection electrode 352 may have an island shape.

Therefore, the second connection electrode 352 and the anode electrode as the first electrode 221 constituting the organic light-emitting element 220 of the pixel may be made of the same material and may constitute the same layer.

The second connection electrode 352 electrically connects the reference voltage line connection pad 340 and the reference voltage line 341 to each other and, to this end, is preferably formed to have a large area as much as possible in order to reduce or minimize resistance thereof and increase or maximize uniformity of resistance distribution thereof. Further, the second passivation-hole 218 b is formed to have a large area as much as possible to increase or maximize a contact area thereof with the reference voltage line connection pad 340 and the reference voltage line 341.

Further, at least one gas exhaust hole 355 may be formed in a partial region of the second connection electrode 352 as in the first connection electrode 351.

In one example, a third passivation-hole 218 c may be formed on the second VSS voltage line 322, as shown in FIG. 7. As shown in FIG. 8, a third connection electrode 353 may be formed on the third passivation-hole 218 c.

The third passivation-hole 218 c formed on the second VSS voltage line 322 is intended for connecting the second VSS voltage line 322 and the third connection electrode 353 to each other. The third connection electrode 353 is electrically connected to the second VSS voltage line 322 via the third passivation-hole 218 c.

In order to reduce the resistance by increasing or maximizing the contact area between the second VSS voltage line 322 and the third connection electrode 353, the third passivation-hole 218 c may have a bar shape corresponding to the second VSS voltage line 322.

Further, when forming the third connection electrode 353 at a lower end portion of the transparent display panel 300, an effect may occur that a difference between vertical levels of the lower end portion of the transparent display panel 300 and an upper end portion of the transparent display panel 300 in which the first connection electrode 351 and the second connection electrode 352 may be removed.

The third connection electrode 353, the first connection electrode 351 and the second connection electrode may be made of the same material and may constitute the same layer but may be spaced apart from each other. Thus, the third connection electrode 353 is formed to have an island shape.

Accordingly, the third connection electrode 353 and the anode electrode as the first electrode 221 constituting the organic light-emitting element 220 of the pixel may be made of the same material and may constitute the same layer.

The bank layer 231 may be formed on the first connection electrode 351, the second connection electrode 352 and the third connection electrode 353. As shown in FIG. 9, the bank layer 231 may form a dam 380 disposed in the non-display region NDA to surround the display region DA. The dam 380 may include at least one dam 380 as patterned. When the dam 380 is formed on the first substrate 200, the dam 380 may serve to prevent an encapsulating material used to form the encapsulating layer 250 from flowing to an outside.

The dam 380 may be disposed in the non-display region NDA, and may be disposed to surround the lighting tester 375 and the first VDD voltage line 331 disposed in the non-display region NDA.

In one example, a fourth connection electrode 354 is formed on the bank layer 231, and is connected to the cathode electrode as the second electrode 225 of the pixel. The fourth connection electrode 354 is electrically connected to the VSS voltage line to apply a VSS voltage to the cathode electrode of the pixel. In this case, the cathode electrode and the fourth connection electrode 354 may be formed integrally with each other.

One end of the fourth connection electrode 354 is electrically connected to the first connection electrode 351 to which the VSS voltage is applied, while the other end of the fourth connection electrode 354 is electrically connected to the third connection electrode 353, thereby to apply the VSS voltage to the cathode electrode.

As shown in FIG. 9, FIG. 10 and FIG. 16, the bank layer 231 is formed on the first connection electrode 351. A first bank-hole 231 a is formed on the first connection electrode 351 and is formed by removing a partial region of the bank layer 231, thereby to expose the first connection electrode 351 to an outside. Thus, the first connection electrode 351 may be electrically connected to one end of the fourth connection electrode 354 via the first bank-hole 231 a.

When the VSS voltage is applied to the fourth connection electrode 354, the fourth connection electrode 354 is not directly connected to the first VSS voltage line 321, but the fourth connection electrode 354 is connected thereto via the first connection electrode 351 made of a same material as an anode electrode, thereby to reduce an electrical resistance.

To increase or maximize the contact area between the first connection electrode 351 and the fourth connection electrode 354, the first bank-hole 231 a of the bank layer 231 on the first connection electrode 351 may be formed in a bar shape as in the reference voltage line 341.

Further, the first bank-hole 231 a may be formed in a corresponding manner to the reference voltage line 341 or the first VSS voltage line 321. For example, in some cases, the first bank-hole 231 a may overlap with either the reference voltage line 341 or the first VSS voltage line 321.

For example, when the first bank-hole 231 a is formed on a separate circuit region such as an ESD protection circuit region 371, there may be a problem that the bank-hole is formed in a region where a flatness is poor.

Further, when the first bank-hole 231 a is formed on a line far away from the first VSS voltage line 321 such as the first VDD voltage line 331, a current path of the fourth connection electrode 354 which is electrically connected to the first VSS voltage line 321 via the first bank-hole 231 a becomes longer. Thus, the resistance increases correspondingly.

For example, when a length of a connection to the fourth connection electrode 354 as the cathode electrode of the high resistance rather than the anode electrode of the low resistance is larger, the overall resistance may be greater.

Thus, according to an embodiment of the present disclosure, the first bank-hole 231 a is preferably formed on the reference voltage line 341 or the first VSS voltage line 321.

When the first bank-hole 231 a is formed on the reference voltage line 341, an inclined face of the hole may be removed to obtain a high flatness, thereby to reduce resistance variation than when a bank-hole is formed in a portion of the bank layer 231 on which no line is formed.

Further, when the first bank-hole 231 a is formed on the first VSS voltage line 321, a length of a connection between the fourth connection electrode 354 and the first VSS voltage line 321 becomes smaller, thereby reducing the resistance.

As shown in FIG. 9 and FIG. 10, a second bank-hole 231 b formed by removing a partial region of bank layer 231 is formed in a portion of the bank layer 231 on the third connection electrode 353 electrically connected to the second VSS voltage line 322, thereby to electrically connect an opposite portion of the fourth connection electrode 354 to the third connection electrode 353.

In this case, the second bank-hole 231 b is formed to correspond to a third passivation-hole 218 c on the second VSS voltage line 322. Thus, while the second VSS voltage line 322, the third connection electrode 353 and the fourth connection electrode 354 are in a stacked state, they electrically contact each other at the same position. For example, in some cases, the second bank-hole 231 b overlaps with a third passivation-hole 218 c on the second VSS voltage line 322.

In addition, the second VSS voltage line 322 is not directly connected to the cathode electrode, but is connected thereto via the third connection electrode 353 as a low-resistance anode electrode, thereby to reduce resistance.

Due to the connection structure of the fourth connection electrode 354, the VSS voltage may be applied to the fourth connection electrode 354. Thus, the VSS voltage may be applied to the cathode electrode of the organic light-emitting element 220. That is, the VSS voltage applied from the VSS voltage line connection pad 320 may be applied to the fourth connection electrode 354 via the first VSS voltage line 321 and the first connection electrode 351.

The fourth connection electrode 354 may extend across an entirety of the display region DA including the first VDD voltage line 331, the reference voltage line 341, the first VSS voltage line 321, the second VDD voltage line 332 and the second VSS voltage line 322.

For example, as shown in FIG. 15, the cathode electrode may extend across an entirety of the display region DA including the second VDD voltage line 332 and the second VSS voltage line 322, and may be surrounded with the dam 380.

In one example, the GIP circuit region 360 includes a GIP division block 361 and a clock signal line region 363, as shown in FIG. 17.

The GIP division block 361 includes at least one GIP division block that divides the gate lines GL into multiple blocks and drives each of the multiple blocks in each of multiple display driving periods. The clock signal line region 363 may include at least one clock signal lines to control nodes of the GIP circuit region 360.

The GIP division block 361 and the clock signal line region 363 may be alternately arranged in a direction away from the display region DA.

Specifically, non-transparent and thick VSS voltage lines may be omitted in left and right portions of the non-display region NDA left and right to the display region DA. Thus, the GIP circuit region 360 may occupy a region increased by the omitted area.

Therefore, the GIP division block 361 and the clock signal line region 363 constituting the GIP circuit region 360 may be arranged in a non-compacted manner. Thus, a transparent region may be secured even in the GIP circuit region 360.

For example, in a case where a space of the GIP circuit region 360 is narrow, the GIP division block 361 and the clock signal line region 363 must be arranged in a very dense manner to increase or maximize space utilization. Thus, it is difficult to secure a separate transparent region In the GIP circuit region 360.

To the contrary, when the space of the GIP circuit region 360 increases as in one embodiment of the present disclosure, the GIP division block 361 having a non-transparent region at a larger amount and the clock signal line region 363 having a transparent region at a larger amount may be alternately arranged in the GIP circuit region 360 in a distinguished manner. Thus, the transparent region may be secured to the maximum even in the GIP circuit region 360.

In other words, according to one embodiment of the present disclosure, the VSS voltage line is omitted in one side region of the non-display region NDA out of the display region DA where the GIP circuit region 360 is disposed, as shown in FIG. 17 and FIG. 18. Thus, reduction of a transparent region due to the non-transparent VSS voltage line may be reduced or minimized.

Therefore, the lighting tester 375 may be disposed between the dam 380 and the GIP circuit region 360, but the VSS voltage line may not be disposed between the dam 380 and the GIP circuit region 360.

A transparent display device should be capable of displaying image information to be displayed while having the same properties as those of a transparent glass substrate. A transparent display device having such characteristics may be configured as a complex transparent display device in which the display information and a spatial situation behind the transparent display device overlap with each other. Representative examples thereof include a head-up-display (HUD) used in airplanes and automobiles.

The head-up-display used in a vehicle as shown in FIG. 19 is mounted on a windshield of the vehicle to display various driving information to a driver while allowing the driver's front view to be secured.

Therefore, in the head-up-display, high visibility of display information is required. When a haze value is high, visibility of display information is not good. Thus, it is important to make the haze value as low as possible.

The haze is related to clarity of an object (or objects) seen through the transparent display device. Therefore, in a transparent display device having a high transmittance but a high haze value, there is a problem in that a driver sees the object in a blurry manner, and thus visibility of display information is deteriorated. Occurrence of the haze in the transparent display device may be attributed to the following light characteristics.

FIG. 20A shows a long-distance diffraction pattern by a single slit. FIG. 20B is an illustration of a diffraction effect in a single slit.

Diffraction of a wave refers to a phenomenon in which a wave front is bent when the wave encounters an obstacle or a slit. In diffraction using a single slit, a surface wave of a certain wavelength having exited the slit forms a myriad of spherical waves.

In this regard, light may be treated as a wave in that a diffraction phenomenon occurs in a slit experiment using light as shown in FIG. 20A. As the light passes through the slit, diffraction appears in the same way as the surface wave. However, a myriad of new spherical waves interfere with each other, resulting in occurrence of contrasting diffraction patterns.

FIG. 20B shows Fraunhoffer diffraction in which a diffraction pattern is viewed at a long distance from a diffracting object. The Fraunhoffer diffraction occurs when all rays are considered as parallel rays, and the diffraction pattern is the same regardless of the distance.

A condition under which the Fraunhoffer diffraction occurs in a single slit may be calculated as follows.

When a difference between paths of two light beams traveling at an edge and a center of the slit respectively is r1−r2,

${r\; 1} - {r\; 2{= {\frac{a}{2}\sin {\theta.}}}}$

In the connection, a m-th offset interference condition in which an offset interference occurs is

${{\frac{a}{2}\sin \theta} = {\pm \frac{m\lambda}{2}}}.$

Since θ is usually much smaller than 1, a darkened point corresponds to a point away

$\theta = {{{\pm \frac{m\lambda}{a}}\mspace{14mu} {or}\mspace{14mu} {ym}} = {{\pm \frac{m\lambda}{a}}R}}$

from the center.

FIG. 21A to FIG. 21D shows results of a double slit experiment for a particle, a wave, light, and an electron, respectively.

When particles pass through a double slit, a distribution of particles hitting a screen appears as a simple sum of single distributions of the particles passing through a single slit as shown in FIG. 21A.

That is, in this case, a bright band appears on a portion of the screen corresponding not to a center of the screen but to a slit position. When the wave passes through the double slit, the brightest band appears at the center of the screen, as shown in FIG. 21B. This allow knowing whether interference occurs. Since the particles do not interfere with each other, a distribution of particles is strong at a position where they may pass through the slit in a best manner.

In one example, when the light passes through the double slit as shown in FIG. 21C, an interference pattern resulting from a fact that the particle property thereof disappears and the wave passes therethrough occurs. Electron is generally considered to be a particle. However, when an electron accelerated at a high speed passes through a double slit as shown in FIG. 21D, a result appears as the same result as that of a double slit experiment of the wave.

That is, it may be seen that even when the particles pass through the double slit at a sufficiently high speed, the same interference as that occurring in the wave occurs. As a result, it may be seen that light has the wave-particle duality in that light is a wave generated by particles as photons that is sufficiently fast.

In this way, light has the properties of waves and particles at the same time. Thus, when the light encounters a slit having a periodic pattern, overlapping and offsetting occur, resulting in periodic diffraction. Consequently, the diffraction phenomenon due to the wave-particle duality of light may vary depending on a shape of the transmissive region which acts as a slit in the transparent display device.

For example, FIG. 22 shows an arrangement of transmissive regions having a typical quadrangle shape in a transparent display device.

Multiple transmissive regions TAij in which i is a row number, and j is a column number (i and j are natural numbers) are arranged in a matrix type. Thus, the transmissive regions in a first row include TA11, TA12, TA13 . . . , the transmissive regions in a second row include TA21, TA22, TA23 . . . , and the transmissive regions in a third row include TA31, TA32, TA33 . . . . Similarly, the transmissive regions in a first column are TA11, TA21, TA31 . . . , the transmissive regions in a second column are TA12, TA22, TA32 . . . , and the transmissive regions in a third column are TA13, TA23, TA33 . . . .

In this case, each transmissive region has a rectangular shape having all internal angles of 90 degrees. As a result, each of the transmissive regions TA21 and TA23 adjacent to the transmissive region TA22 to the same row has a vertical side facing and parallel to a vertical side of the transmissive region TA22.

Further, each of the transmissive regions TA12 and TA32 adjacent to the transmissive region TA22 in the same column has a horizontal face facing and parallel to a horizontal side of the transmissive region TA22. That is, each of all sides of the transmissive region TA22 faces and is parallel to a corresponding side of each of adjacent transmissive regions. The same principle may be equally applied to other transmissive regions.

Since light transmits the transmissive regions, they may play the same role as the slit illustrated in the double slit experiment above. Therefore, occurrence or non-occurrence, and an intensity of diffraction of light may vary depending on shapes and an arrangement structure of the transmissive regions.

Diffraction of light is caused by periodic repetition of lines constituting the slit, and may be more clearly generated when adjacent lines constituting the slit have a periodicity in a parallel manner to each other or when the slits are periodically arranged.

Therefore, in the transparent display device, when the transmissive regions, each having the rectangular shape are arranged in a matrix type having regularity and periodicity in a parallel manner as shown in FIG. 22, the diffraction phenomenon of light may be clearly observed.

FIG. 23 shows the diffraction phenomenon of light generated when light is incident onto a central region of a transparent display device having the transmissive region shape and the arrangement structure of the transmissive regions as shown in FIG. 22.

As may be seen in FIG. 23, it may be seen that the diffraction phenomenon of light appears very clearly around the central region where the light is incident. As the diffraction phenomenon of light becomes more apparent in the transparent display device, the haze also increases. As a result, the clarity or visibility of the transparent display device is reduced.

Therefore, there is a need for a new pixel structure having a shape of a transmissive region that may reduce or minimize the diffraction of light caused by periodic repetition of lines in the transmissive regions. Thus, the present disclosure provides a new pixel structure including transmissive regions having a new transmissive region shape as follows. A transparent display panel according to another embodiment according to the present disclosure includes a substrate having a display region including a plurality of light-emitting regions and a plurality of transmissive regions, and a plurality of line regions disposed on the substrate and extending across the display region, wherein an outer contour of each of the transmissive regions is at least partially curved.

For example, in an embodiment of the present disclosure shown in FIG. 24, an outer contour of each of the transmissive regions may be partially curved. Specifically, the transmissive region TA22 has four outwardly convex sides corresponding to four sides of a dotted virtual rectangle drawn inside the transmissive region. The same feature may be applied to other transmissive regions.

Thus, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA21 and TA23 adjacent to the transmissive region TA22 may not be parallel to each other. Further, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA12 and TA32 adjacent to the transmissive region TA22 in the same column may not be parallel to each other.

In another embodiment according to the present disclosure shown in FIG. 25, an outer contour of each of transmissive regions may be partially curved. Specifically, the transmissive region TA22 has six outwardly convex sides corresponding to six sides of a dotted virtual hexagon drawn inside the transmissive region. The same feature may be applied to other transmissive regions.

Thus, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA21 and TA23 adjacent to the transmissive region TA22 may not be parallel to each other. Further, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA12 and TA32 adjacent to the transmissive region TA22 in the same column may not be parallel to each other.

In still another embodiment according to the present disclosure shown in FIG. 26, an outer contour of each of transmissive regions has a circular shape. Specifically, the transmissive region TA22 is formed to have a circular shape. The same feature may be applied to other transmissive regions.

Thus, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA21 and TA23 adjacent to the transmissive region TA22 may not be parallel to each other. Further, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA12 and TA32 adjacent to the transmissive region TA22 in the same column may not be parallel to each other.

In other words, all sides of the transmissive region TA22 in FIG. 24 to FIG. 26 may not be parallel to all sides of each of adjacent transmissive regions thereto. The same features may be applied to other transmissive regions.

Therefore, even when the transmissive regions, each having the shape shown in FIG. 24 to FIG. 26, are arranged in a matrix type, parallel regularity and periodicity of the transmissive regions acting as slits are avoided, thereby reducing or minimizing the diffraction of light.

Further, in another embodiment according to the present disclosure, each of transmissive regions may be formed in an elliptical shape. Due to this elliptical shape, the parallel regularity and periodicity of the transmissive regions that act as the slit as illustrated above may be avoided, thereby reducing or minimizing the diffraction of light as much as possible.

Although FIG. 24 to FIG. 26 show that an entirety of the outer contour of each of the transmissive regions is curved by way of example, the present disclosure is not limited thereto. Even when only a portion of the contour of the transmissive region is curved, the parallel regularity and periodicity of the transmissive regions may be avoided, thereby reducing or minimizing the diffraction of light.

Therefore, in the transparent display panel including transmissive regions, each having the outer contour being at least partially curved, diffraction of light may be reduced or minimized, thereby to reduce the haze level. As a result, the clarity or visibility of the transparent display device may be improved.

FIG. 27 shows the diffraction phenomenon of light generated when light is shot onto a central region of a transparent display device having a transmissive region of a circular shape and an arrangement structure of the transmissive regions as shown in FIG. 26. As may be seen in FIG. 27, substantially no diffraction of light is generated around the central region where light is incident.

Thus, non-occurrence of the diffraction of light in a transparent display device having a transmissive region of a circular shape and an arrangement structure of the transmissive regions as shown in FIG. 26 is clearer, compared to FIG. 23 which shows the result when light is incident onto the central region of the transparent display device having a conventional quadrangle transmissive region shape.

The diffraction of light is reduced or minimized, especially when the transmissive region has a circular shape. Thus, in order to minimize the diffraction interference of light, it is desirable to form the transmissive region to have a shape approximate to a circle as much as possible. However, when the outer contour of the transmissive region is at least partially curved, as in the circular transmissive region, an area of the transmissive region may be reduced. Thus, it may be difficult to design a pixel including the light-emitting region and the line region.

Therefore, hereinafter, another embodiment according to the present disclosure capable of designing an optimized transmissive region and an optimized light-emitting region while reducing or minimizing diffraction interference of light is illustrated.

A transparent display panel according to another embodiment of the present disclosure includes a substrate including a display region including a plurality of light-emitting regions and a plurality of transmissive regions, and a plurality of line regions disposed on the substrate and extending across the display region, wherein each of the transmissive region has a polygonal shape, and all internal angles of the polygon are obtuse.

For example, as shown in FIG. 28, each of transmissive regions has a polygonal shape whose all internal angles are obtuse. That is, the polygon having all internal angles being an obtuse angle include all of polygons having at least 5 sides. The polygon may include all of the sides of lengths equal to each other.

Specifically, in FIG. 28, the transmissive region has a hexagon shape, and more specifically, a regular hexagon shape. This is one example. As shown in FIG. 28, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA21 and TA23 adjacent to the transmissive region TA22 may not be parallel to each other. However, mutually facing sides of the transmissive region TA22 and each of transmissive regions TA12 and TA32 adjacent to the transmissive region TA22 in the same column may be parallel to each other.

Thus, when transmissive regions with hexagonal shapes are arranged as shown in FIG. 28, mutually facing sides of transmissive regions adjacent to each other in the same row may not be parallel to each other. Thus, the parallel regularity and periodicity of the transmissive regions are avoided, such that diffraction of light may be reduced or minimized as much as possible.

In other words, when mutually facing sides of transmissive regions adjacent to each other in the same row and/or column are not parallel to each other, diffraction of light may be reduced or minimized, compared to when mutually facing sides of transmissive regions adjacent to each other in the same row and/or column are parallel to each other.

In the hexagonal transmissive region shape shown in FIG. 28, a length of each of mutually facing sides of transmissive regions adjacent to each other in the same column is small. Thus, even when mutually facing sides of transmissive regions adjacent to each other in the same column are parallel to each other, the diffraction phenomenon of light may be reduced.

Therefore, even when transmissive regions, each having the shape shown in FIG. 28, are arranged in a matrix type in a transparent display device, the parallel regularity and periodicity of the transmissive regions acting as slits are avoided, such that diffraction of light may be reduced or minimized as much as possible.

In another embodiment according to the present disclosure, as shown in FIG. 29, each of the transmissive regions has an octagon shape, especially, a regular octagon shape having all internal angles being an obtuse angle. This is one example. The octagon as shown in FIG. 29 is more approximate to a circle than the hexagon is, such that an effect similar to that as achieved by the transmissive region having a circular shape that reduces or minimizes diffraction of light may be obtained by the shape of FIG. 29.

In the octagonal transmissive region shape shown in FIG. 29, a length of each of mutually facing sides of transmissive regions adjacent to each other in the same column is small. Thus, even when mutually facing sides of transmissive regions adjacent to each other in the same column are parallel to each other, the diffraction phenomenon of light may be reduced.

Therefore, even when transmissive regions, each having the shape shown in FIG. 29, are arranged in a matrix type in a transparent display device, the parallel regularity and periodicity of the transmissive regions acting as slits are avoided, such that diffraction of light may be reduced or minimized as much as possible.

That is, a transmissive region of a polygonal shape in which all internal angles are obtuse, in particular, a transmissive region having a regular polygonal shape in which all internal angles are obtuse has a shape more approximate to a circle, thereby reducing or minimizing diffraction of light.

Further, an area of a transmissive region of a polygonal shape in which all internal angles are obtuse may be larger than an area of the curved or circular shaped transmissive region. Thus, when using a transmissive region of a polygonal shape in which all internal angles are obtuse, the pixel design and the line region design may be easier than that when using the curved or circular shaped transmissive region.

Therefore, a transparent display panel including a transmissive region having a polygonal shape in which all internal angles are obtuse may secure a maximum transmission region with the reduced haze level and may facilitate the design of the pixel and the line region.

Hereinafter, the arrangement shape of the light-emitting regions and the transmissive regions according to an embodiment of the present disclosure will be described in more detail, based on the embodiment in which the transmissive region has an octagon among the various embodiments of the transmissive region shapes as exemplified above.

As shown in FIG. 30, a transparent display panel according to an embodiment of the present disclosure includes a substrate having a display region including a plurality of light-emitting regions and a plurality of transmissive regions, and line regions disposed on the substrate while extending across the display region. In this case, the transmissive region has a polygonal shape in which all internal angles are obtuse.

The transparent display panel may be composed of a transmission region including a plurality of transmissive regions TA through which light is transmitted, and a non-transmission region NTA through which light is not transmitted. In the transmission region, a plurality of transmissive regions TA are arranged in a matrix composed of a plurality of rows of transmissive regions and a plurality of columns of transmissive regions.

In this case, a plurality of transmissive regions TA arranged in the same row may be referred to as one transmissive region row. For example, one transmissive region row may indicate the transmissive regions running horizontally (e.g., along the x-axis). A plurality of transmissive regions arranged in the same column may be referred to as one transmissive region column. For example, one transmissive region column may indicate the transmissive regions running vertically (e.g., up and down or along the y-axis). In the connection, the row direction refers to a horizontal direction of the substrate and coincides with the X-axis direction. The column direction is defined as the vertical direction of the substrate coinciding with the Y-axis direction.

The non-transmissive region NTA may include a light-emitting region in which light is emitted and a non-light-emitting region in which light is not emitted. The light-emitting region refers to a region in which a light-emitting region EA of a sub-pixel is disposed. The non-light-emitting region may contain a plurality of line regions CLA, each extending in the vertical direction of the substrate.

In this case, the plurality of line regions are column line regions CLA1, CLA2, CLA3, CLA4 . . . , each extending in a column direction. The plurality of line regions contains data lines and various voltage lines extending in the column direction. Further, a pixel circuit region PCA connected to the light-emitting region of each sub-pixel may be disposed in the non-light-emitting region.

The pixel circuit region PCA may be disposed under the light-emitting region EA and may be aligned with the light-emitting region EA. The PCA partially overlaps the light-emitting region EA and the non-overlapping region of the PCA region may be contained in the non-light-emitting region.

In addition, the line region CLA is placed in a non-light-emitting region. However, when the light-emitting region EA partially overlaps the line region CLA, a portion of the region CLA overlapping the light-emitting region EA may act as a light-emitting region. A plurality of transmissive regions (TAij, where i is the row number, and j is the column number, i and j are natural numbers) may be arranged in matrix type.

The transparent display panel of FIG. 30 is one example having a sub-pixel arrangement structure of RG-BG, but the present disclosure is not limited thereto. For example, a first color sub-pixel may be a red sub-pixel including a first color light-emitting region emitting red light. A second color sub-pixel may be a green sub-pixel including a second color light-emitting region emitting green light. A third color sub-pixel may be a blue sub-pixel including a third color light-emitting region emitting blue light. However, the present disclosure is not limited thereto.

The first color sub-pixel Rij_SP includes a first color light-emitting region Rij and a first color pixel circuit region Rij_CA that is electrically connected to the first color light-emitting region Rij to control light emission from the first color light-emitting region Rij. The first color pixel circuit region Rij_CA may be disposed under the first color light-emitting region Rij while partially overlapping therewith. Thus, at least a partial region of the first color pixel circuit region Rij_CA does not overlap with the first color light-emitting region Rij, and thus may be exposed to an outside.

In this case, a portion of the first color pixel circuit region Rij_CA as exposed to the outside may be positionally biased relative to the first color light-emitting region Rij, for example, may be biased to a right side to the first color light-emitting region Rij. Thus, it is possible to more efficiently arrange the emitting region and the pixel circuit region in an entire pixel arrangement structure.

In the partial region of the first color pixel circuit region Rij_CA as exposed to the outside, a first color sub-pixel contact-hole Rij_H that electrically connects the first color light-emitting region Rij and the first color pixel circuit region Rij_CA to each other may be formed.

Further, each of the second color sub-pixel Gij SP and the third color sub-pixel Bij_SP may be configured in the same manner as the first color sub-pixel Rij_SP as exemplified above in terms of the light-emitting region, the pixel circuit region, the sub-pixel contact-hole, etc. Thus, additional overlapping descriptions thereof will be omitted.

The first color sub-pixel is placed between adjacent rows of the transmissive regions. For example, first color sub-pixels R11_SP, R12_SP, and R13_SP are disposed between the transmissive regions TA11, TA12, and TA13 in the first row and the transmissive regions TA21, TA22, and TA23 in the second row, respectively. Thus, the first color light-emitting regions R11, R12, and R13 may be disposed between the transmissive regions TA11, TA12, and TA13 in the first row and the transmissive regions TA21, TA22, and TA23 in the second row, respectively.

The first color sub-pixel is disposed between the second color sub-pixel and the third color sub-pixel. Thus, the first color light-emitting region is disposed between the second color light-emitting region and the third color light-emitting region.

Further, the first color sub-pixel is disposed between adjacent line region CLAs among the plurality of line regions CLA arranged in the vertical direction of the substrate and does not overlap with the line regions CLA. The second color sub-pixel and the third color sub-pixel are disposed on the line region CLA and partially overlap the line region CLA.

For example, the second color sub-pixels G12_SP and G14_SP in the same row as the first color sub-pixels R11_SP, R12_SP, and R13_SP among the second color sub-pixels at least partially overlap the second column line region CLA2 and the fourth column line region CLA4, respectively. The second color sub-pixels G21_SP and G23_SP in the same row as the first color sub-pixels R21_SP, R22_SP, and R23_SP at least partially overlap the first column line region CLA1 and the third column line region CLA3, respectively.

The third color sub-pixels B11_SP and B13_SP in the same row as the first color sub-pixels R11_SP, R12_SP, and R13_SP among the third color sub-pixels at least partially overlap the first column line region CLA1 and the third column line region CLA3, respectively. The third color sub-pixels B22_SP and B24_SP in the same row as the first color sub-pixels R21_SP, R22_SP, and R23_SP at least partially overlap the second column line region CLA2 and the fourth column line region CLA4, respectively.

In other words, as in a configuration in which the second color sub-pixel B11_SP and the third color sub-pixel G21_SP are spaced apart in the column direction and disposed on the first column line region CLA1, the second color sub-pixel and the third color sub-pixel are disposed on one column line region and are alternately arranged in the column direction.

Further, as in a configuration in which the second color sub-pixel B11_SP and the third color sub-pixel G12_SP in the same row are disposed on the first column line region CLA1 and the second column line region CLA2 adjacent thereto respectively, the second color sub-pixel and the third color sub-pixel are alternately arranged in the row direction and are disposed on column line regions adjacent to each other in the row direction respectively.

Therefore, the first color sub-pixel R11_SP, the second color sub-pixel G12_SP, the first color sub-pixel R12_SP, and the third color sub-pixel B13_SP are sequentially arranged in the first row. In the second row adjacent to the first row, the first color sub-pixel R21_SP, the third color sub-pixel B22_SP, the first color sub-pixel R22_SP, and the second color sub-pixel G23_SP are sequentially arranged to correspond to the above pattern.

Therefore, the second color sub-pixel G12_SP, the first color sub-pixel R12_SP, and the third color sub-pixel B13_SP consecutively arranged in the first row, and the third color sub-pixel B22_SP, the first color sub-pixel R22_SP, and the second color sub-pixel G23_SP arranged in the second row surround the transmissive region TA22. When using this arrangement shape as a basic unit, a plurality of units are arranged in a matrix manner in the display region.

That is, in the transmissive region according to an embodiment of the present disclosure, when the above-described basic unit is defined as one pixel, a single transmissive region is not divided into two or more in a single pixel, thereby to effectively suppress increase in the haze.

In this regard, the variation in the haze value based on the shape of the transmissive region and based on the division or non-division of the transmissive region may be identified based on FIG. 31 and FIG. 32. Specifically, FIG. 31A shows a configuration in which the transmissive region has a quadrangle shape, and three transmissive regions correspond to one pixel. FIG. 31B shows a configuration in which the transmissive region has a quadrangle shape, and two transmissive regions correspond to one pixel. FIG. 31C shows a configuration in which one transmissive region corresponds to one pixel while the transmissive region has a circular shape as in one embodiment of the present disclosure.

All of FIG. 31A to FIG. 31C are experiment results based on 145 ppi (pixels per inch). In FIG. 31A, a haze value of 2.76% was measured. In FIG. 31B, a haze value of 2.03% was measured. Therefore, it may be seen that the haze value decreases by 26.4% as the number of transmissive regions corresponding to one pixel decreases from three to two.

In FIG. 31C, a haze value of 1.33% was measured. Therefore, in FIG. 31C, the haze value decreased by 34.5% compared to that of FIG. 31B. Thus, it may be clearly seen that as the number of transmissive regions decreased from 2 to 1, and the transmissive region has the circular shape, the haze value further decreases.

FIG. 32 shows a graph of the haze value when ppi is 200 ppi, 100 ppi, and 145 ppi respectively, and when the transmissive region has a quadrangle shape, and the number of transmissive regions corresponding to one pixel is 3 (A), when the transmissive region has a quadrangle shape, and the number of transmissive regions corresponding to one pixel is 2 (B), and when a circular transmissive region is provided, and the number of transmissive regions corresponding to one pixel is 1 (C).

As may be seen from the graph result value in FIG. 32 that in the configuration C in which a circular transmissive region is disposed, but the number of transmissive regions corresponding to one pixel is 1, the haze value is reduced or minimized for all ppi.

The first color light-emitting region, the second color light-emitting region and the third color light-emitting region are arranged to correspond to the first color sub-pixel, the second color sub-pixel and the third color sub-pixel, respectively. Thus, the light-emitting regions are arranged in the same manner as the arrangement structure of the sub-pixels as illustrated above.

As shown in FIG. 30, the transmissive region has an octagonal shape. The first color light-emitting region has a rectangular shape. In this case, the shape of the first color light-emitting region is formed so as be surrounded by the bank layer 231 as shown in FIG. 34. Specifically, in the first color light-emitting region, the bank layer 231 may be removed to be opened.

Further, each of the second color light-emitting region and the third color light-emitting region may have a polygonal shape, for example, a hexagon. A shape of each of the second color light-emitting region and the third color light-emitting region is formed so as be surrounded by the bank layer 231. Specifically, in each of the second and third color light-emitting regions, the bank layer 231 may be removed to be opened.

An area of one first color light-emitting region may be smaller than an area of each of one second color light-emitting region and one third color light-emitting region. Specifically, since the red light-emitting region has a longer lifespan than that of each of the green and blue light-emitting regions, the former has better lifespan reliability and light-emitting efficiency. Therefore, it is desirable to form the red light-emitting region to have a smaller area than that of each of the green and blue light-emitting regions. For example, the first color light-emitting region, the second color light-emitting region, and the third color light-emitting region may be formed at an area ratio of approximately 1:1.8:1.8.

Each of the second color light-emitting region and the third color light-emitting region may be disposed on the corresponding line region and may at least partially overlap therewith. In this case, each of the second color light-emitting region and the third color light-emitting region may be arranged to be symmetrical around each corresponding line region. Due to this arrangement structure, the transparent display panel according to an embodiment of the present disclosure may have a pixel arrangement structure that may make the most of a light-emitting area efficiently.

In another embodiment of the present disclosure, as shown in FIG. 33, each of the second color sub-pixel and the third color sub-pixel may include a light-emitting region further extending along the line region in the column direction of the line region.

In order to secure the light-emitting region as much as possible, as shown in FIG. 33, for example, the third color sub-pixel B11_SP and the second color sub-pixel G21_SP arranged in the column direction of the first line region CLA1 expand such that a spacing therebetween is larger.

Preferably, the third color sub-pixel B11_SP and the second color sub-pixel G21_SP arranged in the column direction of the first line region CLA1 may be further extended to an extent such that distal ends of the two sub-pixels abut each other. However, the distal ends thereof may have a predefined separation space therebetween considering a process margin.

In particular, when the second electrode of the organic light-emitting diode, for example, the cathode electrode is made of a metal such as Ag having a low sheet resistance, a separate contact structure is not required to lower the resistance of the cathode electrode. Thus, as shown in FIG. 33, the area of each of the color sub-pixels may be expanded as much as possible on the line region.

FIG. 34 and FIG. 35 show cross-sections of a I-I′ region and a J-J′ region in FIG. 30, respectively. FIG. 34 is a cross-sectional view of a first color sub-pixel region. Specifically, the passivation layer 218 as a planarization layer is disposed on the first color pixel circuit region R_PCA. The first electrode 221 of the organic light-emitting diode 220, for example, an anode electrode, is formed on the passivation layer 218.

The bank layer 231 is formed on the first electrode 221. In order to expose a portion of the first electrode 221 corresponding to the light-emitting region to the outside, a portion of the bank layer 231 corresponding to the light-emitting region is removed and thus the bank layer is patterned. That is, the bank layer 231 may serve as a boundary that defines the light-emitting region, thereby determining a shape of the light-emitting region, and may also serve as a boundary between the sub-pixel and the transmissive region.

The shape of the first electrode 221 is determined based on the shape into which the bank layer 231 is patterned. In order to increase or maximize the transmittance and the light-emitting region, it is desirable to form the bank layer to have a minimum width allowable in a mask process for forming the bank layer 231.

On and over the first electrode 221, the organic light-emitting layer 223 is formed to cover the bank layer 231. The second electrode 225, for example, a cathode electrode, is formed on the organic light-emitting layer 223. As the organic light-emitting layer 223 and the second electrode 225 are stacked on the first electrode 221 in an overlapping manner to form the organic light-emitting diode 220, a region of the first electrode 221 exposed to an outside through an open region in the bank layer 231 may act as the light-emitting region.

The encapsulating layer 250 may be formed on the second electrode 225. A color filter CF may be formed on the encapsulating layer 250. The color filter CF may have the same color as a corresponding light-emitting region. A first color filter R_CF corresponding to the first color sub-pixel R_SP may have the same color as the first color.

When using the color filter CF, it is possible to reduce reflectance and increase the color purity of RGB color. The color filter CF may extend to a boundary between the transmissive region TA and the light-emitting region EA and thus may be formed in the non-transmissive region NTA. Therefore, a region where the color filter CF is formed may be defined as the light-emitting region.

The top substrate as the second substrate 270 may be adhered onto the color filter CF. Further, to prevent damage to the organic film layer which is vulnerable to high temperatures, the top substrate may be disposed on the color filter CF using a COE (color-filter on encap) approach in which a low-temperature color filter process is performed on the substrate without a bonding process.

In one example, FIG. 35 is a cross-sectional view of a border region between the first color sub-pixel R_SP and the second color sub-pixel G_SP.

The passivation layer 218 as the planarization layer is disposed on the pixel circuit region PCA, specifically, the first color pixel circuit region R_PCA and the second color pixel circuit region G_PCA. The first electrode 221 of the organic light-emitting diode 220, for example, an anode electrode is formed on the passivation layer 218.

The first electrodes 221 spaced apart from each other are respectively formed in the first color sub-pixel region and the second color sub-pixel region. The bank layer 231 is formed on the first electrode 221. In order to expose a portion of the first electrode 221 corresponding to the light-emitting region to the outside, a portion of the bank layer 231 corresponding to the light-emitting region is removed and then the bank layer is patterned.

That is, the bank layer 231 may serve as a boundary between sub-pixels adjacent to each other. The region corresponding to the bank layer 231 may be a non-transmissive region NTA. On and over the first electrode 221, the organic light-emitting layer 223 is formed to cover the bank layer 231. The second electrode 225 is formed on the organic light-emitting layer 223.

As the organic light-emitting layer 223 and the second electrode 225 are stacked on the first electrode 221 in an overlapping manner to form the organic light-emitting diode 220, the region of the first electrode 221 exposed to the outside through the open region of the bank layer 231 may be a light-emitting region.

The encapsulating layer 250 may be formed on the second electrode 225. The color filter CF may be formed on the encapsulating layer 250.

The first color filter R_CF corresponding to the first color sub-pixel R_SP may have the first color. The second color filter G_CF corresponding to the second color sub-pixel G_SP may have the second color.

Both of the first color filter R_CF and the second color filter G_CF may be formed to be as wide as possible so that at least a partial region thereof overlaps the bank layer 231.

In one example, the first color sub-pixel R_SP and the second color sub-pixel G_SP are adjacent to each other. Thus, in order to reduce or minimize mixing of light beams of different colors adjacent to each other and to clarify a boundary between different color light-emitting regions, a non-transparent black matrix may be disposed between the first color filter R_CF and the second color filter G_CF.

The black matrix may be formed in a pattern corresponding to the bank layer 231 forming the boundary, and may be formed to be narrower than the bank layer 231 and may be disposed inside the bank layer 231.

In one example, as shown in FIG. 36, the substrate has a non-display region surrounding the display region. The non-display region may include a dummy pixel pattern region DPA arranged to surround the outermost portion of the display region. Specifically, the display region DA includes a plurality of sub-pixels SP. The dummy pixel pattern region DPA may include a plurality of dummy pixels or dummy sub-pixels DSP (see FIG. 37).

The dummy pixel or dummy sub-pixel DSP is formed to reduce or minimize a process deviation and a side effect such as a loading effect that may occur during a manufacturing process of the transparent display device. The dummy pixel DSP may surround the sub-pixel to serve as a kind of a buffer area.

The dummy pixel DSP may have an organic light-emitting element layer and a circuit region such as a driving thin-film transistor as in the sub-pixel. However, a signal is not applied to each element layer and the circuit region of the dummy pixel. Thus, a separate pixel contact-hole SP_H that electrically connect the components thereof to each other is not required. As a result, the organic light-emitting element layer in the dummy pixel pattern region DPA does not emit light. For example, the circuit region such as the driving thin-film transistor of the dummy pixel may not work or operate to emit light.

The dummy pixel pattern region DPA surrounding the outermost portion of the display region DA may include a top row direction region and a bottom row direction region above and below the display region DA, as shown in FIG. 37. The dummy pixel pattern region DPA surrounding the outermost portion of the display region DA may include a left column direction region and a right column direction region left and right to the display region DA as shown in FIG. 37. The static electricity may invade the GIP regions left and right to the display region DA through the gate line. Thus, a left column direction region and a right column direction region of the dummy pixel pattern region DPA may be thicker than a top row direction region and a bottom row direction region thereof. For example, as shown in FIG. 37, the left column direction region may have a width W3 and the bottom row direction region may have a width W₄. In some embodiments, W3 may be greater than W₄. However, other dimensions may be used in other embodiments according to the display design.

Hereinafter, a transparent display panel according to another embodiment of the present disclosure to obtain the effects of the present disclosure as mentioned above without reducing transmittance of the display region, and a transparent display device including the same will be described in detail.

In a transparent display panel including a display region and a non-display region, as shown in FIG. 38, the display region includes a plurality of light-emitting regions, a plurality of transmissive regions, a plurality of line regions spaced apart from each other and arranged in one direction, and a plurality of pixel circuit regions electrically connected to the light-emitting regions to drive the light-emitting regions respectively.

First, each line region CLA extends in the vertical direction of the display region. Alternate adjacent line regions CLA respectively include alternate adjacent VSS voltage connection line 323 and a VDD voltage connection line 333.

In this case, the line region CLA including the VSS voltage connection line 323 includes a plurality of reference voltage (Vref) connection lines 343 arranged symmetrically around the VSS voltage connection line 323, and a plurality of data (Vdata) lines 313 arranged symmetrically around the VSS voltage connection line 323.

In some embodiments, a plurality of reference voltage (Vref) connection lines 343 are adjacently arranged around the VSS voltage connection line 323, and a plurality of data (Vdata) lines 313 are also adjacently arranged around the VSS voltage connection line 323. Here, the plurality of data (Vdata) lines 313 may be arranged adjacent to the outer side of the plurality of reference voltage (Vref) connection lines 343.

Further, line region CLA including the VDD voltage connection line 333 includes a plurality of reference voltage connection lines 343 arranged symmetrically around the VDD voltage connection line 333, and a plurality of data lines 313 arranged symmetrically around VDD voltage connection line 333.

In some embodiments, a plurality of reference voltage connection lines 343 are adjacently arranged around the VDD voltage connection line 333, and a plurality of data lines 313 are also adjacently arranged around the VDD voltage connection line 333. Here, the plurality of data lines 313 may be arranged adjacent to the outer side of the plurality of reference voltage connection lines 343.

For example, when the line region including the VDD voltage connection line 333 is defined as a first column line region CLA1, the first column line region CLA1 includes two reference voltage connection lines 343 symmetrically arranged around the VDD voltage connection line 333, and two data lines 313 symmetrically arranged around the VDD voltage connection line 333.

Further, a second column line region CLA2 immediately adjacent to the first column line region CLA1 includes the VSS voltage connection line 323. In this case, the second column line region CLA2 includes two reference voltage connection lines 343 arranged symmetrically around the VSS voltage connection line 323, and two data lines 313 arranged symmetrically around the VSS voltage connection line 323.

In accordance with the present disclosure, both of the VSS voltage connection line 323 and the VDD voltage connection line 333 extend across the display region. Thus, the non-transparent and thick connection lines, especially, the VSS voltage connection lines may be removed from the non-display region, such that a size of the transparent region of the bezel may be increased or maximized and the bezel may be slimmed.

In particular, instead of disposing the non-transparent and thick VSS voltage connection line in the non-display region, the VSS voltage connection line is formed inside the display region and is divided into a plurality of thin lines. Thus, the VSS voltage connection line may connect the upper first VSS voltage line and a lower second VSS voltage line sandwiching the display region therebetween to each other, thereby to reduce or minimize a decrease in transmittance of the display region.

In other words, when arranging the plurality of VSS voltage connection lines and the plurality of VDD voltage connection lines together with the data lines and the reference voltage connection lines in the display region, a decrease in transmittance of the display region may be reduced or minimized compared to a structure in which the VSS voltage connection line is not formed in the display region.

The plurality of the light-emitting regions include a first second color light-emitting region Rij, a second color light-emitting region Gij, and a third color light-emitting region Bij. Each of the second color light-emitting region and the third color light-emitting region may at least partially overlap each line region. Thus, the first color light-emitting regions may be placed between the line regions adjacent to each other. Each of the second color light-emitting region and the third color light-emitting region may be arranged symmetrically around each line region.

In one example, a first color sub-pixel Rij_SP includes a first color light-emitting region Rij, and a first color pixel circuit region Rij PCA electrically connected to the first color light-emitting region Rij to drive the first color light-emitting region Rij to emit light. The first color light-emitting region Rij and the first color pixel circuit region Rij PCA may be electrically connected to each other via a first color sub-pixel contact-hole Rij H. Further, each of a second color sub-pixel Gij SP and a third color sub-pixel Bij_SP may be configured in the same manner as the first color sub-pixel Rij_SP in terms of the light-emitting region, the pixel circuit region, the sub-pixel contact-hole, etc.

Therefore, a plurality of pixel circuit regions are arranged over the substrate and are electrically connected to the light-emitting regions respectively to drive the light-emitting regions. The pixel circuit regions include the first color pixel circuit region that is electrically connected to the first color light-emitting region, the second color pixel circuit region electrically connected to the second color light-emitting region, and the third color pixel circuit region electrically connected to the third color light-emitting region.

In this case, each of the plurality of pixel circuit regions may be arranged symmetrically with respect to each line region. Further, each pixel circuit region may have a narrower shape as the pixel circuit region extends away from a center of each line region. Specifically, the first color pixel circuit region may be arranged symmetrically to the second color pixel circuit region and the third color pixel circuit region around a corresponding line region.

For example, the second color light-emitting region G12 may be arranged symmetrically around the second column line region CLA2. Further, the first color pixel circuit region R11_PCA and the second color pixel circuit region G12_PCA may be arranged symmetrically to each other around the second column line region CLA2.

Specifically, the first color pixel circuit region R11_PCA has a shape that becomes narrower as the first color pixel circuit region R11_PCA extends away from a center of the second column line region CLA2 in the left direction. The second color pixel circuit region G12_PCA may have a shape that becomes narrower as the second color pixel circuit region extends away from a center of the second column line region CLA2 in the right direction.

In this way, the first color pixel circuit region R12_PCA and the third color pixel circuit region B13_PCA may be arranged symmetrically to each other around the third column line region CLA3.

Further, the first color pixel circuit region may overlap at least partial regions of the first color light-emitting region and the second color light-emitting region, and may overlap at least partial regions of the first color light-emitting region and the third color light-emitting region.

The second color pixel circuit region may overlap at least partial regions of the first color light-emitting region and the second color light-emitting region. The third color pixel circuit region may overlap at least partial regions of the first color light-emitting region and the third color light-emitting region.

The arrangement form of the pixel circuit region is due to the arrangement form of the light-emitting region and the transmissive region. The light-emitting region become narrower as the region extends away from a center of a corresponding line region. Thus, the pixel circuit region is disposed within the light-emitting region so as not to overlap the transmissive region, thereby not to lower the transmittance of the display region.

Therefore, according to the present disclosure, the VSS voltage connection line and the VDD voltage connection line are alternately arranged in the adjacent line regions within the display region. Each pixel circuit region connected to each light-emitting region corresponding to each color has a symmetrical structure. Thus, a new pixel arrangement structure capable of increasing or maximizing an area of the transparent region of the bezel and reducing or minimizing the haze value without reducing the transmittance of the display region may be realized.

In one example, the pixel circuit region may include a driving thin-film transistor, a capacitor, and a plurality of switching thin-film transistors. That is, each of the first color pixel circuit region, the second color pixel circuit region, and the third color pixel circuit region may include a driving thin-film transistor, a capacitor, and a plurality of switching thin-film transistors.

FIG. 39 shows a connection relationship between the line region and the pixel circuit region while enlarging a K-K′ region of FIG. 38. FIG. 40 shows a circuit diagram of the pixel circuit region.

One sub-pixel may include an organic light-emitting diode OLED, a driving thin-film transistor DR, a plurality of switching thin-film transistors T1, T2, T3, T4, and T5, and a capacitor Cst. The switching thin-film transistors may include first to fifth switching thin-film transistors T1, T2, T3, T4, and T5.

The organic light-emitting diode OLED emits light using a current supplied via a driving thin-film transistor DR. An anode electrode of the organic light-emitting diode OLED may be connected to a drain electrode of the driving thin-film transistor DR. A cathode electrode thereof may be connected to a VSS voltage connection line VSS to which a VSS power voltage is supplied. The VSS voltage connection line VSS may act as a low-level voltage line to which a low-level power voltage is supplied.

The organic light-emitting diode OLED may include an anode electrode, an organic light-emitting layer 223, and a cathode electrode. The organic light-emitting layer 223 includes a hole injection layer (HIL), a hole transport layer (HTL), a light-emitting layer (EML), an electron transport layer (ETL), and an electron injection layer (EIL). In the organic light-emitting diode OLED, when voltage is applied to the anode electrode and the cathode electrode, holes and electrons are transferred to the light-emitting layer EML via the hole injection layer (HIL) and the hole transport layer (HTL) and the electron injection layer (EIL) and the electron transport layer (ETL), respectively. The holes and electrons are combined with each other in the light-emitting layer EML to emit light.

The driving thin-film transistor DR is disposed between a VDD voltage connection line VDD to which a VDD power voltage is supplied and the organic light-emitting diode OLED. The driving thin-film transistor DR adjusts a current flowing from the VDD voltage connection line VDD to the organic light-emitting diode OLED based on a voltage difference between the gate electrode and the source electrode.

The gate electrode of the driving thin-film transistor DR may be connected to one electrode of the capacitor Cst and the second electrode of the second switching thin-film transistor T2. The source electrode of the driving thin-film transistor DR may be connected to the anode electrode of the organic light-emitting diode OLED. The drain electrode of the driving thin-film transistor DR may be connected to the VDD voltage connection line VDD. The VDD voltage connection line VDD may act as a high-level voltage line to which a high-level power voltage is supplied.

The first switching thin-film transistor T1 is turned on based on a first gate signal of a first scan line Scan1 to supply a voltage of the data line Vdata to the other electrode of the capacitor Cst. The gate electrode of the first switching thin-film transistor T1 may be connected to the first scan line Scan1. The first electrode of the first switching thin-film transistor T1 may be connected to the data line Vdata. The second electrode of the first switching thin-film transistor T1 may be connected to the other electrode of the capacitor Cst.

The second switching thin-film transistor T2 is turned on based on a second gate signal of a second scan line Scan2 to connect the gate electrode and the drain electrode of the driving thin-film transistor DR to each other. The gate electrode of the second switching thin-film transistor T2 may be connected to the second scan line Scan2. The first electrode of the second switching thin-film transistor T2 may be connected to the drain electrode of the driving thin-film transistor DR. The second electrode of the second switching thin-film transistor T2 may be connected to the gate electrode of the driving thin-film transistor DR.

The third switching thin-film transistor T3 is turned on based on a light-emitting signal of a light-emitting line EM to initialize the other electrode of the capacitor Cst to a reference voltage. The gate electrode of the third switching thin-film transistor T3 may be connected to the light-emitting line EM. The first electrode of the third switching thin-film transistor T3 may be connected to the other electrode of the capacitor Cst. The second electrode of the third switching thin-film transistor T3 may be connected to a reference voltage connection line Vref to which a reference voltage is supplied.

The fourth switching thin-film transistor T4 is turned on based on a light-emitting signal of the light-emitting line EM to connect the drain electrode of the driving thin-film transistor DR and the anode electrode of the organic light-emitting diode OLED to each other. The gate electrode of the fourth switching thin-film transistor T4 may be connected to the light-emitting line EM. The first electrode of the fourth switching thin-film transistor T4 may be connected to the drain electrode of the driving thin-film transistor DR. The second electrode of the fourth switching thin-film transistor T4 may be connected to the anode electrode of the organic light-emitting diode OLED.

The fifth switching thin-film transistor T5 is turned on based on a second gate signal of the second scan line Scan2 to initialize the anode electrode of the organic light-emitting diode OLED to a reference voltage. The gate electrode of the fifth switching thin-film transistor T5 may be connected to the second scan line Scan2. The first electrode of the fifth switching thin-film transistor T5 may be connected to the anode electrode of the organic light-emitting diode OLED. The second electrode of the fifth switching thin-film transistor T5 may be connected to the reference voltage connection line Vref.

The first electrode of each of the first to fifth switching thin-film transistors T1, T2, T3, T4, and T5 may act as a source electrode, and the second electrode thereof may act as a drain electrode. However, the present disclosure is not limited thereto.

The capacitor Cst is formed between the gate electrode of the driving thin-film transistor DR and the second electrode of the first switching thin-film transistor T1. The capacitor Cst stores therein the voltage difference between the voltage of the gate electrode of the driving thin-film transistor DR and the voltage of the second electrode of the first switching thin-film transistor T1.

One electrode of the capacitor Cst may be connected to the gate electrode of the driving thin-film transistor DR, and the second electrode of the second switching thin-film transistor T2. The other electrode of the capacitor Cst may be connected to the second electrode of the first switching thin-film transistor T1 and the first electrode of the third switching thin-film transistor T3.

In one embodiment of the present disclosure, an example in which each of the driving thin-film transistor DR and the first to fifth switching thin-film transistors T1, T2, T3, T4, and T5 may be embodied as a P-type MOSFET (Metal Oxide Semiconductor Field Effect) transistor has been described. However, the present disclosure is limited thereto. Each of the driving thin-film transistor DR and the first to fifth switching thin-film transistors T1, T2, T3, T4, and T5 may be embodied as a N-type MOSFET (Metal Oxide Semiconductor Field Effect) transistor.

In one example, the driving thin-film transistor DR included in the pixel circuit region connected to the first color sub-pixel may at least partially overlap the second color light-emitting region of the second color sub-pixel or the third color light-emitting region of the third color sub-pixel.

For example, as shown in FIG. 38, the first color pixel circuit region R11_PCA connected to the first color sub-pixel R11_SP may at least partially overlap the second color light-emitting region G12 of the second color sub-pixel G12_SP disposed on a right side to the first color sub-pixel R11_SP. Specifically, the driving thin-film transistor DR included in the first color pixel circuit region R11_PCA may at least partially overlap the second color light-emitting region G12.

Further, the pixel circuit regions may be arranged symmetrically to each other around one line region. In this case, one pixel circuit region including a driving thin-film transistor DR driving a light-emitting region at least partially overlapping the line region may be disposed on one side to the line region. The other pixel circuit region related to a different color from that of one pixel region and including a driving thin-film transistor DR driving a light-emitting region between the corresponding line region and a neighboring line region thereto may be disposed on the other side to the line region.

That is, a driving thin-film transistor driving a light-emitting region at least partially overlapping the line region may be disposed on one side to the line region, while a driving thin-film transistor driving a light-emitting region between the line region and a neighboring line region thereto may be disposed on the other side to the line region.

For example, the line region CLA2 at least partially overlaps with the second color light-emitting region G12. The first color pixel circuit region R11_PCA and the second color pixel circuit region G12_PCA may be symmetrically arranged to each other on one side to the line region CLA2.

Thus, a driving thin-film transistor driving the light-emitting region G12 at least partially overlapping the line region CLA2 may be disposed on one side to the line region CLA2. A driving thin-film transistor driving the light-emitting region R11 between the line region CLA2 and the neighboring line region CLA1 thereto may be disposed on the other side to the line region CLA2.

FIG. 41 to FIG. 43 show cross-sectional views of L-L′, M-M′, and N-N′ regions in FIG. 38, respectively.

As shown in FIG. 41, a buffer layer 201, a gate insulating layer 213, a first interlayer insulating layer 215, a second interlayer insulating layer 216 and a passivation layer 218 may be sequentially stacked over the first substrate 200 in this order.

A line region including two reference voltage connection lines 343 spaced apart from each other and arranged symmetrically around the VDD voltage connection line 333 and two data lines 313 spaced apart from each other and arranged symmetrically around from the VDD voltage connection line 333 may be disposed on the passivation layer 218. The VDD voltage connection line 333 may be thicker than each of the reference voltage connection line 343 and the data line 313.

The planarization layer 219 may be disposed on the line region. The organic light-emitting element OLED 220 composed of the first electrode 221, the organic light-emitting layer 223 and the second electrode 225 may be disposed on the planarization layer 219. In this case, the bank layer 231 is formed between the first electrode 221 and the organic light-emitting layer 223.

The encapsulating layer 250 is formed on the second electrode 225. An adhesive layer 251 made of OCR (optical clear adhesive) may be formed on the encapsulating layer 250. The color filter CF may be formed on the adhesive layer 251. The color filter CF may extend to a boundary between the transmissive region TA and the light-emitting region EA such that the color filter CF may be formed in the non-transmissive region NTA region. Therefore, a region where the color filter CF is formed may be defined as a region corresponding to the light-emitting region. Onto the color filter CF, the top substrate as the second substrate 270 may be adhered.

As shown in FIG. 42, a buffer layer 201, a gate insulating layer 213, a first interlayer insulating layer 215, a second interlayer insulating layer 216 and a passivation layer 218 may be sequentially stacked over the first substrate 200 in this order.

On the passivation layer 218, a line region including two reference voltage connection lines 343 spaced apart from each other and arranged symmetrically around the VSS voltage connection line 323, and two data lines 341 spaced apart from each other and arranged symmetrically around the VSS voltage connection line 323 may be disposed. In this case, the VSS voltage connection line 323 may be thicker than each of the reference voltage connection line 343 and the data line 341.

The planarization layer 219 may be disposed on the line region. Descriptions of subsequent components are the same as those made with reference to FIG. 41. Thus, duplicate descriptions thereof will be omitted.

As shown in FIG. 43, the buffer layer 201 is formed on the first substrate 200. On the buffer layer 201, the driving thin-film transistor 210 including an active layer 212, a source electrode 217 a, a drain electrode 217 b, and a gate electrode 214, and the capacitor Cst composed of a first capacitor electrode 204 and a second capacitor electrode 206 may be formed.

In this case, a gate insulating layer 213 may be formed between the active layer 212 and the gate electrode 214 and the first capacitor electrode 204. A first interlayer insulating layer 215 may be formed on the gate electrode 214 and the first capacitor electrode 204, and the second capacitor electrode 206 may be formed on the first interlayer insulating layer 215.

A second interlayer insulating layer 216 may be formed on the second capacitor electrode 206. The source electrode 217 a and the drain electrode 217 b may be formed on the second interlayer insulating layer 216. The passivation layer 218 may extend over the capacitor Cst and the driving thin-film transistor 210. The planarization layer 219 may be formed on the passivation layer 218.

On the planarization layer 219, the organic light-emitting element 220 including the first electrode 221, the organic light-emitting layer 223, and the second electrode 225 may be disposed. In this case, the bank layer 231 may be formed between the first electrode 221 and the organic light-emitting layer 223.

The encapsulating layer 250 may be formed on the second electrode 225. The adhesive layer 251 made of OCR (optical clear adhesive) may be formed on the encapsulating layer 250. The color filter CF may be formed on the adhesive layer 251. Onto the color filter CF, the top substrate as the second substrate 270 may be adhered.

Hereinafter, another embodiment according to the present disclosure in which occurrence of non-uniformity of luminance in the display panel may be reduced or minimized via introduction of an auxiliary electrode region that may reduce an electrical resistance of the transparent electrode will be described in detail.

As shown in FIG. 44 and FIG. 45, the transparent display panel includes a display region and a non-display region. The display region includes a plurality of light-emitting regions, a plurality of transmissive regions TA, a plurality of line regions CLA arranged in one direction and spaced apart from each other, and a plurality of auxiliary electrode regions AE arranged on the line region CLA.

The light-emitting region includes a first color light-emitting region Rij, a second color light-emitting region Gij, and a third color light-emitting region Bij. Each of the second color light-emitting region Gij and the third color light-emitting region Bij may be disposed on a corresponding line region CLA.

The first color light-emitting region Rij may be disposed between the second color light-emitting region Gij and the third color light-emitting region Bij disposed on different line regions CLA respectively. An auxiliary electrode region AE may be disposed between the second color light-emitting region Gij and the third color light-emitting region Bij on the same line region CLA. The light-emitting region may include an organic light-emitting element 220 including a first electrode 221, an organic light-emitting layer 223 and a second electrode 225.

The first electrode 221 may include at least one of transparent conductive materials such as indium tin oxide (ITO), antimony tin oxide (ATO), and indium zinc oxide (IZO).

The organic light-emitting layer 223 has low diffraction properties because the organic light-emitting layer 223 is made of a low organic material having a low step coverage. Thus, when the organic light-emitting layer 223 is formed using a deposition process, the organic light-emitting layer 223 may not penetrate well to a bottom face of a step that is not exposed to an outside. Thus, the organic light-emitting layer 223 may be formed using a vapor deposition process such as an evaporation method having excellent linearity for a vapor deposition target material.

The second electrode 225 may include at least one of transparent conductive materials such as indium tin oxide (ITO), Mg:Ag, Ca—Ag, and indium zinc oxide (IZO).

Particularly, the indium zinc oxide (IZO) is a material with a high step coverage and has high diffraction properties. Thus, when the second electrode 225 made of the IZO is formed via a vapor deposition process, the second electrode 225 may penetrate well to a lower face of a step that is not exposed to an outside.

Each of the plurality of line regions CLA extends in a vertical direction of the display region. Alternately-arranged adjacent line regions CLA includes a VSS voltage connection line 323 and a VDD voltage connection line 333, respectively.

The auxiliary electrode region AE is disposed on the line region CLA including the VSS voltage connection line 323.

Specifically, the auxiliary electrode region AE includes an auxiliary electrode 221 a electrically connected to the VSS voltage connection line 323, a partition wall 241 disposed on the auxiliary electrode 221 a, wherein a width W₄ of a top face (or a top surface) of the partition wall 241 is larger than a width W₅ of a bottom face (or a bottom surface) thereof, and an electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 which directly contact each other. The auxiliary electrode 221 a and the first electrode 221 may be made of the same material and may be formed as the same layer.

For example, when the first electrode 221 acts as an anode electrode, the auxiliary electrode 221 a may be formed via the same patterning process as a patterning process for forming the anode electrode. Thus, the auxiliary electrode 221 a may be spaced apart from the anode electrode.

The auxiliary electrode 221 a serves as a bridge electrode that electrically connects the second electrode 225 to the VSS voltage connection line 323 in the display region. Therefore, the auxiliary electrode 221 a is formed on the VSS voltage connection line 323, and contacts the VSS voltage connection line 323 and electrically connects thereto.

In other words, in an embodiment of the present disclosure, the VSS voltage connection line 323 is disposed in the display region. Thus, the auxiliary electrode 221 a and the VSS voltage connection line 323 may contact each other within the display region. Therefore, a contact-hole may be formed in a passivation layer 218 covering the VSS voltage connection line 323. Via the contact-hole, the auxiliary electrode 221 a and the VSS voltage connection line 323 may be electrically connected to each other.

On the auxiliary electrode 221 a, a bank layer 231 may be disposed. The bank layer 231 may extend along a boundary between the line region CLA and the transmissive region TA. The bank layer 231 may be patterned to cover each of both ends of the auxiliary electrode 221 a. Thus, a portion of the auxiliary electrode 221 a which is not covered with the bank layer 231 may be exposed to an outside.

A boundary portion as the bank layer 231 extending to cover each of the both ends of the auxiliary electrode 221 a may act as a boundary between the non-transmissive region NTA and the transmissive region TA. Therefore, the auxiliary electrode 221 a may be formed to correspond to the line region CLA, and thus may be disposed in the non-transmissive region NTA. For example, the auxiliary electrode 221 a may be formed to correspond to a distal end of each of a pair of data lines 313. However, the present disclosure is not limited thereto.

On a portion of the auxiliary electrode 221 a between opposing adjacent bank layers 231 covering the both ends of the auxiliary electrode 221 a respectively, the partition wall 241 may be formed. The partition wall 241 has a width W₄ of a top face larger than a width W₅ of a bottom face. Thus, the partition wall 24 may have an inverse tapered shape. However, the present disclosure is not limited thereto. The partition wall 241 may be disposed on the auxiliary electrode 221 a and may contact the auxiliary electrode 221 a.

Since the width W₄ of the top face of the partition wall 241 is larger than the width W₅ of the bottom face thereof, the top face of the partition wall 241 acts as a kind of an eave. Therefore, the auxiliary electrode 221 a disposed under the partition wall 241 may have a region in which the auxiliary electrode 221 a overlaps the top face of the partition wall 241 serving as the eave, but is not in contact with the partition wall 241. The auxiliary electrode 221 a and the second electrode 225 contact directly each other in this region to form the electrode contact EC.

That is, the electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 which contact directly each other is disposed inside of a region of the partition wall 241. In other words, the electrode contact EC is disposed in inner region than end of the partition wall 241, so the electrode contact EC is disposed inwardly than end of the partition wall 241. Accordingly, the electrode contact EC overlaps the top face of the partition wall 241 and is positioned under the partition wall 241.

Specifically, the partition wall 241 includes a first partition wall structure 241 a and a second partition wall structure 241 b stacked on the first partition wall structure 241 a.

Therefore, the electrode contact EC is disposed in a region between one distal end of the first partition wall structure 241 a and one distal end of the second partition wall structure 241 b. Specifically, the electrode contact EC is located in a portion of this region in which the auxiliary electrode 221 a is exposed to an outside.

The first partition wall structure 241 a may be in contact with the auxiliary electrode 221 a, while the second partition wall structure 241 b may be spaced apart from the auxiliary electrode 221 a. Further, the first partition wall structure 241 a may overlap the second partition wall structure 241 b, and may be disposed inside of a region of the second partition wall structure 241 b. In other words, the first partition wall structure 241 a is disposed in inner region than end of the second partition wall structure 241 b, so the first partition wall structure 241 a is disposed inwardly than end of the second partition wall structure 241 b.

A bottom face of the first partition wall structure 241 a acts as the bottom face of the partition wall 241, while a top face of the second partition wall structure 241 b acts as the top face of the partition wall 241. The first partition wall structure 241 a and the bank layer 231 may be made of the same material, and may constitute the same layer. The first partition wall structure 241 a may be formed to be spaced apart from the bank layer 231 covering each of the both ends of the auxiliary electrode 221 a.

Therefore, the bank layer 231 may be absent in a region between the first partition wall structure 241 a and each of the bank layers 231 covering the both ends of the auxiliary electrode 221 a, respectively. Thus, this region may act as an open region BO of the bank layer where the auxiliary electrode 221 a is exposed to an outside.

In this case, the distal end of the second partition wall structure 241 b, that is, the eave of the second partition wall structure 241 b may not overlap the bank layer 231 disposed on each of both ends of the partition wall 241 so as to increase an area of the open region BO of the bank layer as much as possible.

In this case, it is preferable that the eave of the second partition wall structure 241 b coincides with the boundary of the bank layer 231 or is spaced apart therefrom by a certain distance. That is, it is desirable that a width of the open region BO of the bank layer is at least equal to or larger than a width of the electrode contact EC.

In particular, when the eave of the second partition wall structure 241 b coincides with the boundary of the bank layer 231, the electrical resistance of the second electrode may be reduced while an area of the transmission region may be secured as much as possible.

Thus, when the eave of the second partition wall structure 241 b does not overlap the bank layer 231 or is spaced apart therefrom by a certain distance, a region of the electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 which contact directly each other may be secured as much as possible.

The first partition wall structure 241 a may be patterned using the same mask process as a mask process for forming the bank layer 231. The first partition wall structure 241 a may have the same shape as the bank layer 231. However, the present disclosure is not limited thereto.

The first partition wall structure 241 a may have a non-inverse tapered shape in which the first partition wall structure 241 a is gradually narrowed as the first partition wall structure 241 a extends upwardly. A lateral face (or a lateral surface) 241 c of the first partition wall structure 241 a may be gently curved.

The second partition wall structure 241 b may be made of a photoresist material. For example, the second partition wall structure 241 b may be made of a negative photoresist material. However, the present disclosure is not limited thereto.

The second partition wall structure 241 b may have an inverse tapered shape in which the second partition wall structure 241 b is gradually narrowed as the second partition wall structure 241 b extends downwardly. A lateral face (or a lateral surface) 241 d of the second partition wall structure 241 b may be gently curved.

For example, when the second partition wall structure 241 b is made of a negative photoresist material, the second partition wall structure 241 b may be formed as follows.

First, a negative photoresist material is applied to cover the first partition wall structure 241 a, and then a partial region of the material is exposed to a material such as a polymerization initiator through a mask. The region of the negative photoresist exposed to the polymerization initiator is cured via a thermal curing step to form an inverse tapered shape. Then, a rest of the negative photoresist excluding the inverse tapered shape structure is removed via a liquid chemical infiltration process, thereby to form the second partition wall structure 241 b of an inverse tapered shape.

That is, although the partition wall 241 according to an embodiment of the present disclosure includes the first partition wall structure 241 a having a non-inverse tapered shape and the second partition wall structure 241 b having an inverse tapered shape stacked on the first partition wall structure 241 a, an overall shape of the partition wall 241 may have an inverse tapered shape in which a width W₄ of the top face thereof is larger than a width W₅ of the bottom face thereof because the width W₄ of the top face of the second partition wall structure 241 b is larger than the width W₅ of the bottom face of the first partition wall structure 241 a, as shown in FIG. 46A.

Due to the above shape of the partition wall 241, the auxiliary electrode region AE includes the electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 which directly contact each other.

Specifically, at least a portion of a removed region of the bank layer 231 located in a region of the partition wall 241 may be a region of the electrode contact EC. Since the partition wall 241 has the width W₄ of the top face thereof larger than the width W₅ of the bottom face thereof, an at least a portion of a removed region of the bank layer 231 may be screened with a top face of the partition wall 241 and may not contact a bottom face of the partition wall 241, such that the auxiliary electrode 221 a may be exposed to the outside.

In this way, the portion of the auxiliary electrode 221 a which is screened with the top face of the partition wall 241 but does not contact the bottom face of the partition wall 241 may constitute the electrode contact EC.

For example, when the organic light-emitting layer 223 and the second electrode 225 are formed over an entirety of the display region, the auxiliary electrode 221 a and the second electrode 225 may not be in direct contact with each other because the organic light-emitting layer 223 and the second electrode 225 are sequentially stacked on the auxiliary electrode 221 a as exposed to an outside in absence of the partition wall 241.

Further, even in presence of the partition wall 241, the organic light-emitting layer 223 and the second electrode 225 are formed along the partition wall 241 and are connected to each other when the partition wall 241 has a non-inverse tapered shape in which the width W₄ of the top face of the partition wall 241 is smaller than the width W₅ of the bottom face thereof. Thus, the organic light-emitting layer 223 and the second electrode 225 are sequentially stacked on the auxiliary electrode 221 a, so that the auxiliary electrode 221 a and the second electrode 225 may not directly contact each other.

However, as in one embodiment of the present disclosure, when the width W₄ of the top face of the partition wall 241 is larger than the width W₅ of the bottom face thereof, the organic light-emitting layer 223 may be discontinuous (this discontinuity may occur due to the partition wall 241) although the organic light-emitting layer 223 is disposed on the entirety of the display region. Further, the second electrode 225 may be disposed on the entirety of the display region, but may not be discontinuous.

This configuration is due to the low diffraction property of the organic light-emitting layer 223 and the high diffraction property of the second electrode 225. Specifically, the organic light-emitting layer 223 is formed by depositing a material having low diffraction property and high linearity. Thus, the material forming the organic light-emitting layer 223 does not penetrate well to an inner region of the auxiliary electrode 221 a which is screened with the top face of the partition wall 241 which serves as the eave, such that the organic light-emitting layer 223 may not be formed.

Thus, the organic light-emitting layer 223 may be formed in an island form and on the top face of partition wall 241. However, the organic light-emitting layer 223 may not be formed on the auxiliary electrode 221 a that is screened with the partition wall 241. Thus, the organic light-emitting layer 223 may be discontinuous (this discontinuity may occur due to the partition wall 241).

To the contrary, the second electrode 225 is formed by depositing a material having high diffraction properties such as IZO. Thus, the material forming the second electrode 225 may penetrate well to an inner region of the auxiliary electrode 221 a which is screened with the top face of the partition wall 241 which acts like the eave, such that the second electrode 225 may be formed.

In particular, the second electrode 225 may be made of a material having high diffraction property, and, thus may penetrate to a region of the partition wall 241 and cover a side face of the partition wall 241. Thus, the second electrode 225 may be deposited to surround the partition wall 241, and thus the second electrode 225 may not be discontinuous.

In one example, as shown in FIG. 46B, in a region where the first partition wall structure 241 a and the second partition wall structure 241 b contact each other, a bottom face 241 e of the second partition wall structure 241 b may extend in an upwardly inclined manner toward the top face of the second partition wall structure 241 b. Thus, a path of the second electrode 225 surrounding the partition wall 241 may be longer and the second electrode 225 may be continuous.

Further, each of lateral faces of the first partition wall structure 241 a and the second partition wall structure 241 b may be gently curved, thereby to prevent the second electrode 225 surrounding the partition wall 241 from being discontinuous.

As shown in FIG. 46B, in some embodiments, an inward region IW of the partition wall 241 may be defined as a region between one side end 241 f of the first partition wall structure 241 a and one side end 241 g of the second partition wall structure 241 b.

As described above, according to an embodiment of the present disclosure, the second electrode surrounding the partition wall may have the longer path and may be continuous. Thus, a contact area thereof with the auxiliary electrode may be larger compared to a case where the second electrode is discontinuous. Thus, effect of reducing luminance non-uniformity may be more effectively achieved by reducing the electrical resistance of the second electrode.

As shown in FIG. 45, one example in which the second electrode 225 is deposited to surround the partition wall 241 and the second electrode 225 is not discontinuous is set forth. However, the present disclosure is not limited thereto. The second electrode 225 may be discontinuous due to the partition wall 241.

Although the second electrode 225 is discontinuous due to the partition wall 241, the electrode contact EC composed of the portion of the auxiliary electrode 221 a and the portion of the second electrode 225 directly contacting each other may be formed because the second electrode 225 has better diffraction than that of the organic light-emitting layer 223, and thus penetrates deeply to the region of the partition wall 241.

Therefore, the organic light-emitting layer 223 may be absent on an at least a portion of a region where the auxiliary electrode 221 a overlaps the partition wall 241 but does not contact the partition wall 241, specifically, a portion of the auxiliary electrode 221 a close to a bottom of the partition wall 241. The electrode contact EC composed of the portion of the auxiliary electrode 221 a and a portion of the second electrode 225 which are in direct contact with each other may be formed.

In this way, the second electrode 225 makes contact with the auxiliary electrode 221 a via the electrode contact EC, and the auxiliary electrode 221 a is electrically connected to and contacts the VSS voltage connection line 323. As a result, the second electrode 225 may be electrically connected to the VSS voltage connection line 323.

As described above, when the second electrode 225 as a transparent electrode having a high sheet resistance is used, differences between the low-level voltage VSS rise values at various positions in the display panel position increase. As a result, the non-uniformity phenomenon of luminance in the display panel occurs, which may lead to a problem of deterioration of display quality.

However, as in one embodiment of the present disclosure, the auxiliary electrode region AE including the partition wall 241 whose the width W₄ of the top face is larger than the width W₅ of the bottom face thereof is disposed on the line region CLA in the display region. The second electrode 225 of the organic light-emitting element 220 and the VSS voltage connection line 323 may be electrically connected to each other via the auxiliary electrode 221 a, thereby to reduce the electrical resistance of the second electrode 225 as a transparent electrode.

Further, as in one embodiment of the present disclosure, the partition wall 241 whose the width W₄ of the top face is larger than the width W₅ of the bottom face thereof is included in the auxiliary electrode region AE. Thus the organic light-emitting layer 223 may be discontinuous and the second electrode 225 may be prevented from being discontinuous even in the presence of the partition wall 241. Thus, a separate mask process is not required, thereby increasing the efficiency of the process.

In one example, it is preferable that the organic light-emitting layer 223 is not formed on a portion of the auxiliary electrode 221 a as screened with the top face of the partition wall 241. However, the organic light-emitting layer 223 may penetrate to a portion of the region of the partition wall 241 and thus be formed on the auxiliary electrode 221 a.

This may be caused by a design error of the partition wall 241 or other process errors. Further, this may occur because the material forming the organic light-emitting layer 223 has the low diffractive property.

Therefore, when the organic light-emitting layer 223 penetrates to a portion of the region of the partition wall 241 and is formed on the auxiliary electrode 221 a, the area of the electrode contact EC decreases as much as an area where the organic light-emitting layer 223 is formed. Thus, the contact area between the auxiliary electrode 221 a and the second electrode 225 may be reduced.

When the area of the electrode contact EC decreases, the electrical resistance of the second electrode 225 increases correspondingly. Thus, it may be difficult to reduce or minimize luminance non-uniformity of the entire panel region.

Thus, when the partition wall 241 in which the second partition wall structure 241 b is stacked on the first partition wall structure 241 a as a portion of the bank layer 231 and is separated from the auxiliary electrode 221 a is introduced, the area of the electrode contact EC may be further increased, further reducing the electrical resistance of the second electrode 225 as a transparent electrode.

For example, FIG. 47A shows a region of an electrode contact EC that may be formed when a partition wall 241 of a single layer having an inverse tapered shape is formed. FIG. 47B shows a region of an electrode contact EC that may be formed when a partition wall 241 including a stack of a first partition wall structure and a second partition wall structure of an inverse tapered shape as one embodiment of the present disclosure.

As shown in FIG. 47A, when the partition wall 241 has an inverse tapered shape but is formed of a single layer, the area where the partition wall 241 contacts the auxiliary electrode 221 a increases. Thus, the area of the auxiliary electrode 221 a which is screened with the top face of the partition wall 241 but is exposed to the outside may not be relatively large. Accordingly, the area of the electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 directly contacting each other and disposed inside of the region of the partition wall 241 may not be relatively large.

However, as shown in FIG. 47B, when the partition wall 241 is formed by stacking the second partition wall structure 241 b of the inverse tapered shape on the first partition wall structure 241 a, only the first partition wall structure 241 a contacts the auxiliary electrode 221 a, and the second partition wall structure 241 b is spaced apart from the auxiliary electrode 221 a. Therefore, the area of the auxiliary electrode 221 a which is screened with the top face of the partition wall 241 but is exposed to the outside may be relatively large. As a result, the area of the electrode contact EC composed of a portion of the auxiliary electrode 221 a and a portion of the second electrode 225 directly contacting each other and disposed inside of the region of the partition wall 241 may be relatively large.

That is, assuming that a size of the partition wall 241 shown in FIG. 47A and a size of the second partition wall structure 241 b shown in FIG. 47B are the same, the area of the electrode contact EC may increase when the partition wall 241 is formed by stacking the second partition wall structure 241 b of the inverse tapered shape on the first partition wall structure 241 a as shown in FIG. 47B.

Therefore, when introducing the partition wall 241 structure in which the second partition wall structure 241 b is stacked on the first partition wall structure 241 a as a portion of the bank layer 231 and is spaced apart from the auxiliary electrode 221 a as in an embodiment of the present disclosure, the area of the electrode contact EC may be further increased, further reducing the electrical resistance of the second electrode 225. Further, the size of the partition wall 241 may be reduced to improve transmittance.

Further, according to an embodiment of the present disclosure, the auxiliary electrode region AE is formed on each of a plurality of line regions CLA respectively including VSS voltage connection lines 323 extending across the display region. Thus, the electrical connection between the VSS voltage connection line 323 and the auxiliary electrode 221 a may occur within the display region. Thus, the current may be supplied to each pixel in the display region in a smooth manner. Thus, the luminance distribution across the panel may be made more uniform.

For example, when the VSS voltage connection line 323 is not disposed in the display region, but surrounds the display region as the bezel of the non-display region does, the electrical connection of the VSS voltage connection line 323 and the auxiliary electrode 221 a may occur in the non-display region.

Especially, in a large area transparent display device, a difference between the VSS voltage supplied to a pixel near the VSS voltage connection line 323 and the VSS voltage supplied to the pixel in a central portion of the display region far away from the VSS voltage connection line 323 may be large. Thus, the difference between the low-level voltage VSS rise values at the positions of the display panel may increase.

However, as in one embodiment of the present disclosure, each of the plurality of line regions CLA respectively including the VSS voltage connection lines 323 may extend across the display region. In this case, variations of the distances between the multiple of pixels existing in the display panel and the VSS voltage connection lines 323 may be small. Thus, the difference between the low-level voltage VSS rise values at the positions of the display panel may decrease.

Further, the partition wall 241 of the auxiliary electrode region AE may be used as a spacer. Thus, a process to form a separate spacer and a separate region to form a spacer are not required, so that high process efficiency and panel space utilization may be obtained.

FIG. 48A and FIG. 48B show ΔVSS values in a case where the partition wall 241 is present and a case in where the partition wall 241 is absent, respectively. Specifically, FIG. 48A and FIG. 48B show measurements of the low-level voltages VSS of the pixels based on the panel with the number of horizontal pixels of the panel X the number of vertical pixels of the panel being 1440×540.

As shown in FIG. 48A, ΔVSS=1.0161V as the difference between the minimum and maximum values of the low-level voltage was measured when there is no partition wall. On the other hand, as shown in FIG. 48B, ΔVSS=0.2084V as the difference between the minimum and maximum values of the low-level voltage was measured when there is the partition wall.

Accordingly, it may be seen that the difference between the rise values of the low-level voltage VS S at the positions of the panel is remarkably smaller when there is the partition wall, compared to the case where there is no partition wall, thereby reducing or minimizing the non-uniformity of luminance.

FIG. 49A shows variations of an area and an electrical resistance of an electrode contact based on a width of the partition wall.

As shown in FIG. 49A, the electrode contact area increases as the width of the top face of the partition wall increases. Thus, the electrical resistance of the second electrode is reduced. In other words, the electrode contact area and the electrical resistance of the second electrode are inversely proportional to each other. Thus, increasing the width of the top face of the partition wall may allow increasing or maximizing the electrode contact area, such that the electrical resistance of the second electrode is reduced.

FIG. 49B shows variations of an area and an electrical resistance of an electrode contact based on a size of the open region BO of the bank layer.

As may be seen in FIG. 49B, the area of the electrode contact increases as the width of the open region of the bank layer increases. Thus, the electrical resistance of the second electrode is reduced.

In particular, in a section where the width of the open region of the bank layer is smaller than or equal to a certain width, specifically, in a section where the width of the open region of the bank layer is 1.75 μm or smaller, the area of the electrode contact increases rapidly. Thus, the electrical resistance of the second electrode is reduced. In this section, the eave of the partition wall begins to at least partially overlap the bank layer. The eave of the partition wall at least partially overlaps the bank layer, such that the width of the open region of the bank layer becomes smaller than the width of the electrode contact. Thus, the area of the electrode contact may be reduced correspondingly.

However, in a section where the width of the open region of the bank layer is 1.75 μm or greater, that is, in a section where the eave of the partition wall does not overlap the bank layer, the area of the electrode contact increases as the width of the open region of the bank layer increases. Thus, the electrical resistance of the second electrode is reduced correspondingly.

In one example, in a section where the width of the open region of the bank layer is 3.75 μm or greater, the area of the electrode contact is no longer increased and becomes constant. Thus, in order to secure the transmission region as much as possible, it is desirable to set the width of the open region of the bank layer to 3.75 μm or smaller.

The present disclosure may include following aspects and implementations.

A first aspect of the present disclosure provides a transparent display panel including a display region and a non-display region, wherein the display region includes: a plurality of light-emitting regions; a plurality of transmissive regions; a plurality of line regions spaced from each other, each line region extending in one direction; and a plurality of auxiliary electrode regions arranged on a corresponding line region; wherein the light-emitting region includes an organic light-emitting element including a first electrode, an organic light-emitting layer, and a second electrode, wherein at least one of the line regions includes a VSS voltage connection line, wherein the auxiliary electrode region is disposed on the line region including the VSS voltage connection line, wherein the auxiliary electrode region includes: an auxiliary electrode electrically connected to the VSS voltage connection line; a partition wall disposed on the auxiliary electrode, wherein a width of a top face of the partition wall is larger than a width of a bottom face thereof; and an electrode contact composed of a portion of the auxiliary electrode and a portion of the second electrode which directly contact each other, wherein the electrode contact is positioned inwardly than end of the partition wall.

In one implementation of the first aspect, the light-emitting region includes a first color light-emitting region, a second color light-emitting region and a third color light-emitting region, wherein each of the second color light-emitting region and the third color light-emitting region is disposed on a corresponding line region, wherein the first color light-emitting region is disposed between the second color light-emitting region and the third color light-emitting region disposed on the different line regions, respectively, wherein the auxiliary electrode region is disposed between the second color light-emitting region and the third color light-emitting region disposed on the same line region.

In one implementation of the first aspect, the second electrode is made of indium zinc oxide (IZO).

In one implementation of the first aspect, the partition wall includes a first partition wall structure and a second partition wall structure stacked on the first partition wall structure, wherein the first partition wall structure is in contact with the auxiliary electrode, wherein the second partition wall structure is spaced apart from the auxiliary electrode.

In one implementation of the first aspect, a lateral face of the second partition wall structure is curved.

In one implementation of the first aspect, in a region where the first partition wall structure contacts the second partition wall structure, a bottom face of the second partition wall structure extends in an upward inclined manner toward the top face of the second partition wall structure.

In one implementation of the first aspect, the first partition wall structure overlaps the second partition wall structure, and is disposed inwardly than end of the second partition wall structure.

In one implementation of the first aspect, the transparent display panel further comprises a bank layer extending along a boundary between the line region and the transmissive region, wherein the first partition wall structure and the bank layer are made of the same material and constitute the same layer.

In one implementation of the first aspect, the second partition wall structure and the bank layer do not overlap each other.

In one implementation of the first aspect, the auxiliary electrode and the first electrode are made of the same material and constitute the same layer.

In one implementation of the first aspect, the transparent display panel further comprises a first VSS voltage line and a second VSS voltage line disposed in the non-display region while the display region is interposed therebetween, wherein the VSS voltage connection line electrically connects the first VSS voltage line and the second VSS voltage line to each other.

In one implementation of the first aspect, the electrode contact is a region between one side end of the first partition wall structure and one side end of the second partition wall structure.

A second aspect of the present disclosure provides a transparent display device including the transparent display panel as defined above, a data driver supplying a data voltage to the transparent display panel, a gate driver supplying a scan signal to the transparent display panel, and a timing controller that controls the gate driver and the data driver.

As described above, the present disclosure is described with reference to the drawings. However, the present disclosure is not limited by the embodiments and drawings disclosed in the present specification. It will be apparent that various modifications may be made thereto by those skilled in the art within the scope of the present disclosure. Furthermore, although the effect resulting from the features of the present disclosure has not been explicitly described in the description of the embodiments of the present disclosure, it is obvious that a predictable effect resulting from the features of the present disclosure should be recognized.

The various embodiments described above can be combined to provide further embodiments. All of the U.S. patents, U.S. patent application publications, U.S. patent applications, foreign patents, foreign patent applications and non-patent publications referred to in this specification and/or listed in the Application Data Sheet are incorporated herein by reference, in their entirety. Aspects of the embodiments can be modified, if necessary to employ concepts of the various patents, applications and publications to provide yet further embodiments.

These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure. 

1. A transparent display panel including a display region and a non-display region, the display region comprising: a plurality of light-emitting regions; a plurality of transmissive regions; and a plurality of line regions spaced apart from each other, each line region extending in one direction, wherein the light-emitting region includes an organic light-emitting element including a first electrode, an organic light-emitting layer, and a second electrode, wherein at least one of the line regions includes a VSS voltage connection line, wherein an auxiliary electrode region is on the line region including the VSS voltage connection line, and wherein the auxiliary electrode region includes: an auxiliary electrode electrically connected to the VSS voltage connection line; a partition wall disposed on the auxiliary electrode, wherein a width of a top face of the partition wall is larger than a width of a bottom face thereof, wherein the top face of the partition wall is opposite the bottom face of the partition wall; and an electrode contact including a portion of the auxiliary electrode and a portion of the second electrode which contact each other and are electrically connected to each other, wherein the electrode contact is positioned inwardly with respect to an end of the partition wall.
 2. The transparent display panel of claim 1, wherein the organic light-emitting layer is formed of a material having a higher diffraction property than that of the second electrode.
 3. The transparent display panel of claim 1, wherein the light-emitting region includes a first color light-emitting region, a second color light-emitting region, and a third color light-emitting region, wherein each of the second color light-emitting region and the third color light-emitting region is on a corresponding line region, wherein the first color light-emitting region is disposed between the second color light-emitting region and the third color light-emitting region on different line regions, and wherein the auxiliary electrode region is disposed between the second color light-emitting region and the third color light-emitting region on a same line region.
 4. The transparent display panel of claim 1, wherein the second electrode is made of indium zinc oxide.
 5. The transparent display panel of claim 1, wherein the partition wall includes a first partition wall structure and a second partition wall structure stacked on the first partition wall structure, wherein the first partition wall structure is in contact with the auxiliary electrode, and wherein the second partition wall structure is spaced apart from the auxiliary electrode.
 6. The transparent display panel of claim 5, wherein a width of a top face of the second partition wall structure is larger than a width of a bottom face of the first partition wall structure.
 7. The transparent display panel of claim 5, wherein the first partition wall structure has a non-inverse tapered shape in which the first partition wall structure is gradually narrowed as the first partition wall structure extends upwardly.
 8. The transparent display panel of claim 5, wherein the second partition wall structure has an inverse tapered shape in which the second partition wall structure is gradually narrowed as the second partition wall structure extends downwardly.
 9. The transparent display panel of claim 5, wherein a lateral face of the second partition wall structure is curved.
 10. The transparent display panel of claim 5, wherein in a region where the first partition wall structure contacts the second partition wall structure, a bottom face of the second partition wall structure extends in an upward inclined manner toward the top face of the second partition wall structure.
 11. The transparent display panel of claim 5, wherein the first partition wall structure overlaps with the second partition wall structure, and is disposed inwardly with respect to an end of the second partition wall structure.
 12. The transparent display panel of claim 5, wherein the transparent display panel further comprises a bank layer extending along a boundary between the line region and the transmissive region, and wherein the first partition wall structure and the bank layer are made of a same material and formed as a same layer.
 13. The transparent display panel of claim 12, wherein the bank layer has an open region where the auxiliary electrode is exposed to outside.
 14. The transparent display panel of claim 13, wherein the open region has a width in a range from 1.75 μm to 3.75 μm.
 15. The transparent display panel of claim 8, wherein the second partition wall structure and the bank layer do not overlap with each other.
 16. The transparent display panel of claim 1, wherein the auxiliary electrode and the first electrode are made of a same material and formed as a same layer.
 17. The transparent display panel of claim 1, wherein the transparent display panel further comprises a first VSS voltage line and a second VSS voltage line disposed in the non-display region with the display region interposed therebetween, and wherein the VSS voltage connection line electrically connects the first VSS voltage line and the second VSS voltage line to each other.
 18. The transparent display panel of claim 5, wherein inward region of the partition wall is a region between one side end of the first partition wall structure and one side end of the second partition wall structure.
 19. The transparent display panel of claim 1, wherein an outer contour of each of the plurality of transmissive regions is at least partially curved.
 20. A display device, comprising: a transparent display panel including a display region and a non-display region, wherein the display region includes: a plurality of light-emitting regions; a plurality of transmissive regions; and a plurality of line regions spaced apart from each other, each line region extending in one direction, wherein the light-emitting region includes an organic light-emitting element including a first electrode, an organic light-emitting layer, and a second electrode, wherein at least one of the line regions includes a VSS voltage connection line, wherein an auxiliary electrode region is disposed on the line region including the VSS voltage connection line, and wherein the auxiliary electrode region includes: an auxiliary electrode electrically connected to the VSS voltage connection line; a partition wall disposed on the auxiliary electrode, wherein a width of a top face of the partition wall is larger than a width of a bottom face thereof; and an electrode contact including a portion of the auxiliary electrode and a portion of the second electrode which contact each other and are electrically connected each other, wherein the electrode contact is positioned inwardly with respect to an end of the partition wall. 